Redox-Bohr effect in the tetrahaem cytochrome c3 from Desulfovibrio vulgaris: a model for energy transduction mechanisms

 Using potentiometric titrations, two protons were found to participate in the redox-Bohr effect observed for cytochrome c ₃ from Desulfovibrio vulgaris (Hildenborough). Within the framework of the thermodynamic model previously presented, this finding supports the occurrence of a concerted proton-assisted 2e^– step, ideally suited for the coupling role of cytochrome c ₃ to hydrogenase. Furthermore, at physiological pH, it is shown that when sulfate-reducing bacteria use H₂ as energy source, cytochrome c ₃ can be used as a charge separation device, achieving energy transduction by energising protons which can be left in the acidic periplasmic side and transferring deenergised electrons to sulfate respiration. This mechanism for energy transduction, using a full thermodynamic data set, is compared to that put forward to explain the proton-pumping function of cytochrome c oxidase.     

Electron transfer between hydrogenases and mono- and multiheme cytochromes in Desulfovibrio ssp

 A comparative study of electron transfer between the 16 heme high molecular mass cytochrome (Hmc) from Desulfovibrio vulgaris Hildenborough and the [Fe] and [NiFe] hydrogenases from the same organism was carried out, both in the presence and in the absence of catalytic amounts of cytochrome c ₃. For comparison, this study was repeated with the [NiFe] hydrogenase from D. gigas. Hmc is very slowly reduced by the [Fe] hydrogenase, but faster by either of the two [NiFe] hydrogenases. In the presence of cytochrome c ₃, in equimolar amounts to the hydrogenases, the rates of electron transfer are significantly increased and are similar for the three hydrogenases. The results obtained indicate that the reduction of Hmc by the [Fe] or [NiFe] hydrogenases is most likely mediated by cytochrome c ₃. A similar study with D. vulgaris Hildenborough cytochrome c ₅₅₃ shows that, in contrast, this cytochrome is reduced faster by the [Fe] hydrogenase than by the [NiFe] hydrogenases. However, although catalytic amounts of cytochrome c ₃ have no effect in the reduction by the [Fe] hydrogenase, it significantly increases the rate of reduction by the [NiFe] hydrogenases. Received: 14 April 1998 / Accepted: 25 June 1998     

The sequence of electron carriers in the reaction of cytochromec oxidase with oxygen

Kinetic studies of the electron transfer processes performed by cytochrome oxidase have assigned rates of electron transfer between the metal centers involved in the oxidation of ferrocytochromec by molecular oxygen. Transient-state studies of the reaction with oxygen have led to the proposal of a sequence of carriers from cytochromec, to Cu_A, to cytochromea, and then to the binuclear (i.e., cytochromea ₃-Cu_B) center. Electron exchange rates between these centers agree with relative center-to-center distances as follows; cytochromec to Cu_A 5–7 Å, cytochromec to cytochromea 20–25 Å, Cu_A to cytochromea 14–16 Å and cytochromea to cytochrome a₃-Cu_B 8–10 Å. It is proposed that the step from cytochromea to the binuclear center is the key control point in the reaction and that this step is one of the major points of energy transduction in the reaction cycle.     

Reinvestigation of the steady-state kinetics and physiological function of the soluble NiFe-hydrogenase I of Pyrococcus furiosus

Pyrococcus furiosus has two types of NiFe-hydrogenases: a heterotetrameric soluble hydrogenase and a multimeric transmembrane hydrogenase. Originally, the soluble hydrogenase was proposed to be a new type of H₂ evolution hydrogenase, because, in contrast to all of the then known NiFe-hydrogenases, the hydrogen production activity at 80°C was found to be higher than the hydrogen consumption activity and CO inhibition appeared to be absent. NADPH was proposed to be the electron donor. Later, it was found that the membrane-bound hydrogenase exhibits very high hydrogen production activity sufficient to explain cellular H₂ production levels, and this seems to eliminate the need for a soluble hydrogen production activity and therefore leave the soluble hydrogenase without a physiological function. Therefore, the steady-state kinetics of the soluble hydrogenase were reinvestigated. In contrast to previous reports, a low K_m for H₂ (~20 μM) was found, which suggests a relatively high affinity for hydrogen. Also, the hydrogen consumption activity was 1 order of magnitude higher than the hydrogen production activity, and CO inhibition was significant (50% inhibition with 20 μM dissolved CO). Since the K_m for NADP⁺ is ~37 μM, we concluded that the soluble hydrogenase from P. furiosus is likely to function in the regeneration of NADPH and thus reuses the hydrogen produced by the membrane-bound hydrogenase in proton respiration.     

Purification, characterization and gene sequence analysis of a novel cytochrome c co-induced with reductive dechlorination activity in Desulfomonile tiedjei DCB-1

The sulfate-reducing bacterium, Desulfomonile tiedjei DCB-1, conserves energy for growth from reductive dechlorination of 3-chlorobenzoate via halorespiration. To understand this respiratory process better, we examined electron carriers from different cellular compartments of D. tiedjei. A 50-kDa cytochrome from the membrane fraction was found to be co-induced with dechlorination activity. This inducible cytochrome was extracted from the membrane fractions by Tris-HCl buffer containing ammonium sulfate at 35% saturation and was purified to electrophoretic homogeneity by phenyl superose, Mono Q, and hydroxyapatite chromatography. The purified cytochrome had a high-spin absorption spectrum. In a pH titration experiment, the absorption spectrum of the inducible cytochrome shifted to low spin at pH 13.2. The midpoint potential of the inducible cytochrome at pH 7.0 was –342 mV. The NH₂-terminal amino acid sequence of the inducible cytochrome was determined and was used to obtain inverse PCR products containing the sequence of the gene encoding the inducible cytochrome. The ORF was 1398 bp and coded for a protein of 52.6 kDa. Two c-type heme-binding domains were identified in the COOH-terminal half of the protein. A putative signal peptide of 26 residues was found at the NH₂-terminal end. The protein sequence was not found to have substantial sequence similarity to any other sequence in GenBank. We conclude that this is a c-type cytochrome substantially different from previously characterized c-type cytochromes. Received: 30 May 1997 / Accepted: 29 July 1997     

Kinetics and interaction studies between cytochrome c3 and Fe-only hydrogenase from Desulfovibrio vulgaris hildenborough

Hydrogenases from Desulfovibrio are found to catalyze hydrogen uptake with low potential multiheme cytochromes, such as cytochrome c₃, acting as acceptors. The production of Fe-only hydrogenase from Desulfovibrio vulgaris Hildenborough was improved with respect to the growth phase and media to determine the best large-scale bacteria growth conditions. The interaction and electron transfer from Fe-only hydrogenase to multiheme cytochrome has been studied in detail by both BIAcore and steady-state measurements. The electron transfer between [Fe] hydrogenase and cytochrome c₃ appears to be a cooperative phenomenon (h = 1.37). This behavior could be related to the conductivity properties of multihemic cytochromes. An apparent dissociation constant was determined (2 × 10^-7 M). The importance of the cooperativity for contrasting models proposed to describe the functional role of the hydrogenase/cytochrome c₃ complex is discussed. Presently, the only determined structure is from [NiFe] hydrogenase and there are no obvious similarities between [NiFe] and [Fe] hydrogenase. Furthermore, no crystallographic data are available concerning [Fe] hydrogenase. The first results on crystallization and X-ray crystallography are reported. Proteins 33:590–600, 1998. © 1998 Wiley-Liss, Inc.     

Respiratory energy transduction by membrane fragments of the phytopathogenic bacteria Pseudomonas cichorii and Pseudomonas aptata

The energy transduction by respiratory membranes from the fluorescent phytopathogenic bacteria Pseudomonas cichorii and Pseudomonas aptata has been examined. Both species have shown to perform ATP synthesis linked to oxidation of NADH with P/2e^- ratios ranging between 0.25 and 0.42. This phosphorylation activity is largely insensitive to antimycin A (10^-6 M) and KCN (5·10^-6 M) in membranes from P. aptata, a strain deficient in c type complement (Zannoni 1982). In contrast, the phosphorylation efficiency is partially lowered by antimycin A and KCN in P. cichorii a strain containing a branched respiratory chain (Zannoni 1982). Oxidation of NADH by ubiquinone-1 (UQ-1) in antimycin A-treated membranes from these two pseudomonads is not coupled to ATP generation. This finding indicates that both strains contain a nonenergy conserving membrane-bound NADH dehydrogenase.The location of the sites of energy conservation was investigated by respiratory-induced quenching of the fluorescence of atebrine. This approach has confirmed the P/2e^--ratios measurements along with indication of a energy conserving step at the UQ/cyt. b levels of both bacterial strains. This study has also shown that the cytochrome c oxidase activity by P. cichorii is linked to a proton gradient generation which in turn drives ATP synthesis (P/2e^-=0.1). Previous data indicated that a high-potential cytochrome of b type (cyt. b380, Em_7.0=+380 mV) is involved in the cytochrome c oxidase activity of P. cichorii (Zannoni 1982). The possibility that this bacterial strain is endowed with a terminal b type oxidase operating with a proton pump mechanism is therefore suggested.     

Bioreduction of platinum salts into nanoparticles: a mechanistic perspective

A mechanism for the bioreduction of H₂PtCl₆ and PtCl₂ into platinum nanoparticles by a hydrogenase enzyme from Fusarium oxysporum is proposed. Octahedral H₂PtCl₆ is too large to fit into the active region of the enzyme and, under conditions optimum for nanoparticle formation (pH 9, 65°C), undergoes a two-electron reduction to PtCl₂ on the molecular surface of the enzyme. This smaller molecule is transported through hydrophobic channels within the enzyme to the active region where, under conditions optimal for hydrogenase activity (pH 7.5, 38°C) it undergoes a second two-electron reduction to Pt(0). H₂PtCl₆ was unreactive at pH 7.5, 38°C; PtCl₂ was unreactive at pH 9, 65°C.     

The mechanism of energy conservation and transduction by mitochondrial cytochrome c oxidase

Oxidation of ferrocytochrome c by molecular oxygen catalysed by cytochrome c oxidase (cytochrome aa₃) is coupled to translocation of H⁺ ions across the mitochondrial membrane. The proton pump is an intrinsic property of the cytochrome c oxidase complex as revealed by studies with phospholipid vesicles inlayed with the purified enzyme. As the conformation of cytochrome aa₃ is specifically sensitive to the electrochemical proton gradient across the mitochondrial membrane, it is likely that redox energy is primarily conserved as a conformational “strain” in the cytochrome aa₃ complex, followed by relaxation linked to proton translocation. Similar principles of energy conservation and transduction may apply on other respiratory chain complexes and on mitochondrial ATP synthase.     

Dependence on the F<Subscript>0</Subscript>F<Subscript>1</Subscript>-ATP synthase for the activities of the hydrogen-oxidizing hydrogenases 1 and 2 during glucose and glycerol fermentation at high and low pH in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Escherichia coli has four [NiFe]-hydrogenases (Hyd); three of these, Hyd-1, Hyd-2 and Hyd-3 have been characterized well. In this study the requirement for the F₀F₁-ATP synthase for the activities of the hydrogen-oxidizing hydrogenases Hyd-1 and Hyd-2 was examined. During fermentative growth on glucose at pH 7.5 an E. coli F₀F₁-ATP synthase mutant (DK8) lacked hydrogenase activity. At pH 5.5 hydrogenase activity was only 20% that of the wild type. Using in-gel activity staining, it could be demonstrated that both Hyd-1 and Hyd-2 were essentially inactive at these pHs, indicating that the residual activity at pH 5.5 was due to the hydrogen-evolving Hyd-3 enzyme. During fermentative growth in the presence of glycerol, hydrogenase activity in the mutant was highest at pH 7.5 attaining a value of 0.76 U/mg, or ~50% of wild type activity, and Hyd-2 was only partially active at this pH, while Hyd-1 was inactive. Essentially no hydrogenase activity was measured at pH 5.5 during growth with glycerol. At this pH the mutant had a hydrogenase activity that was maximally only ~10% of wild type activity with either carbon substrate but a weak activity of both Hyd-1 and Hyd-2 could be detected. Taken together, these results demonstrate for the first time that the activity of the hydrogen-oxidizing hydrogenases in E. coli depends on an active F₀F₁-ATP synthase during growth at high and low pH.     

Kinetic parameters for hydrogen evolution by the NAD-linked hydrogenase of Alcaligenes eutrophus

The hydrogen-evolving reaction of the purified soluble NAD-linked hydrogenase of Alcaligenes eutrophus was used to determine kinetic parameters of the enzyme. The H₂-evolving activity with methyl viologen as electron mediator was 20-fold as compared to that with NADH. In the assay with dithionite-reduced methyl viologen (K _m 0.7 mM) the hydrogenase was most active at a redox potential of –560 mV and exhibited a pH optimum of 7.0. The K _m for protons, the second substrate for H₂ evolution, was 6.2 nM. With electrochemically reduced methyl viologen the pH optimum was shifted to pH 6.0. Double-reciprocal plots of reaction rates versus proton concentrations intercepted at the ordinate for different methyl viologen concentrations. At different pH values such an intercept was also observed with the dye as the varied substrate. The kinetic data are diagnostic for an ordered bisubstrate mechanism where both substrates are bound before the product H₂ is released. Hydrogenase coupled to thylakoid membranes resulted in a constant H₂ evolution rate over 6 h. The system appeared to be limited by the capacity of the thylakoid membranes.     

Evolution of the Cytochrome c Oxidase Proton Pump

The superfamily of quinol and cytochrome c terminal oxidase complexes is related by a homologous subunit containing six positionally conserved histidines that ligate a low-spin heme and a heme–copper dioxygen activating and reduction center. On the basis of the structural similarities of these enzymes, it has been postulated that all members of this superfamily catalyze proton translocation by similar mechanisms and that the Cu_A center found in most cytochrome c oxidase complexes serves merely as an electron conduit shuttling electrons from ferrocytochrome c into the hydrophobic core of the enzyme. The recent characterization of cytochrome c oxidase complexes and structurally similar cytochrome c:nitric oxide oxidoreductase complexes without Cu_A centers has strengthened this view. However, recent experimental evidence has shown that there are two ubiquinone(ol) binding sites on the Escherichia coli cytochrome bo ₃ complex in dynamic equilibrium with the ubiquinone(ol) pool, thereby strengthening the argument for a Q(H₂)-loop mechanism of proton translocation [Musser SM et al. (1997) Biochemistry 36:894–902]. In addition, a number of reports suggest that a Q(H₂)-loop or another alternate proton translocation mechanism distinct from the mitochondrial aa ₃ -type proton pump functions in Sulfolobus acidocaldarius terminal oxidase complexes. The possibility that a primitive quinol oxidase complex evolved to yield two separate complexes, the cytochrome bc ₁ and cytochrome c oxidase complexes, is explored here. This idea is the basis for an evolutionary tree constructed using the notion that respiratory complexity and efficiency progressively increased throughout the evolutionary process. The analysis suggests that oxygenic respiration is quite an old process and, in fact, predates nitrogenic respiration as well as reaction-center photosynthesis. Received: 11 June 1997 / Accepted: 30 October 1997     

Cytochrome oxidase: pathways for electron tunneling and proton transfer

 Electrons from cytochrome c, the substrate of cytochrome oxidase, a redox-linked proton pump, are accepted by Cu_A in subunit II. From there they are transferred to the proton pumping machinery in subunit I, cytochrome a and cytochrome a ₃–Cu_B. The reduction of the latter site, which is the dioxygen reducing unit, is coupled to proton uptake. Dioxygen reduction involves a peroxide and a ferryl ion intermediate, and it is the transition between these and back to the resting oxidized enzyme that are coupled to proton pumping. The X-ray structures suggest electron–transfer pathways that can account for the observed rates provided that the reorganization energies are small. They also reveal two proton-transfer pathways, and mutagenesis experiments have shown that one is used for proton uptake during the initial reduction of cytochrome a ₃–Cu_B, whereas the other mediates transfer of the pumped protons. Received: 23 March 1998 / Accepted: 11 May 1998     

The tetraheme cytochrome from Shewanella oneidensis MR-1 shows thermodynamic bias for functional specificity of the hemes

Bacteria of the genus Shewanella contain an abundant small tetraheme cytochrome in their periplasm when growing anaerobically. Data collected for the protein isolated from S. oneidensis MR-1 and S. frigidimarina indicate differences in the order of oxidation of the hemes. A detailed thermodynamic characterization of the cytochrome from S. oneidensis MR-1 in the physiological pH range was performed, with data collected in the pH range 5.5–9.0 from NMR experiments using partially oxidized samples and from redox titrations followed by visible spectroscopy. These data allow the parsing of the redox and redox–protonation interactions that occur during the titration of hemes. The results show that electrostatic effects dominate the heme–heme interactions, in agreement with modest redox-linked structural modifications, and protonation has a considerable influence on the redox properties of the hemes in the physiological pH range. Theoretical calculations using the oxidized and reduced structures of this protein reveal that the bulk redox–Bohr effect arises from the aggregate fractional titration of several of the heme propionates. This detailed characterization of the thermodynamic properties of the cytochrome shows that only a few of the multiple microscopic redox states that the protein can access are significantly populated at physiological pH. On this basis a functional pathway for the redox activity of the small tetraheme cytochrome from S. oneidensis MR-1 is proposed, where reduction and protonation are thermodynamically coupled in the physiological range. The differences between the small tetraheme cytochromes from the two organisms are discussed in the context of their biological role.     

Purification and Characterization of Membrane-Associated Hydrogenase from the Deep-Sea Epsilonproteobacterium Hydrogenimonas thermophila

Membrane-associated hydrogenase was purified from the chemolithoautotrophic epsilonproteobacterium Hydrogenimonas thermophila at 152-fold purity. The hydrogenase was found to be localized in the periplasmic space, and was easily solubilized with 0.1% Triton X-100 treatment. Hydrogen oxidation activity was 1,365 μmol H₂/min/mg of protein at 80 °C at pH 9.0, with phenazine methosulphate as the electron acceptor. Hydrogen production activity was 900 μmol H₂/min/mg of protein at 80 °C and pH 6.0, with reduced methyl viologen as the electron donor. The hydrogenase from this organism showed higher oxygen tolerance than those from other microorganisms showing hydrogen oxidation activity. The structural genes of this hydrogenase, which contains N-terminal amino acid sequences from both small and large subunits of purified hydrogenase, were successfully elucidated. The hydrogenase from H. thermophila was found to be phylogenetically related with H₂ uptake hydrogenases from pathogenic Epsilonproteobacteria.     

Laboratoire de Chimie Bactérienne C.N.R.S., Marsielle, France.

Summary Mutants of E. coli, completely devoid of nitrite reductase activity with glucose or formate as donor were studied. Biochemical analysis indicates that they are simultaneously affected in nitrate reductase, nitrite reductase, fumarate reductase and hydrogenase activities as well as in cytochrome c₅₅₂ biosynthesis. The use of an antiserum specific for nitrate reductase shows that the nitrate reductase protein is probably missing. A single mutation is responsible for this phenotype: the gene affected, nir R, is located close to tyr R i.e. at 29 min on the chromosomal map.Abbreviations BV Benzyl-Viologen - NTG N-methyl-N-nitro-N-nitrosoguanidine - NR nitrate reductase - NIR nitrite reductase - FR fumarate reductase - HYD hydrogenase - CYT c₅₅₂ cytochrome c₅₅₂     

Pathways of Proton Transfer in Cytochrome c Oxidase

During the last few years our knowledge of the structure and function of heme copper oxidases has greatly profited from the use of site-directed mutagenesis in combination with biophysical techniques. This, together with the recently-determined crystal structures of cytochrome c oxidase, has now made it possible to design experiments aimed at targeting specific pump mechanisms. Here, we summarize results from our recent kinetic studies of electron and proton-transfer reactions in wild-type and mutant forms of cytochrome c oxidase from Rhodobacter sphaeroides. These studies have made it possible to identify amino acid residues involved in proton transfer during specific reaction steps and provide a basis for discussion of mechanisms of electron and proton transfer in terminal oxidases. The results indicate that the pathway through K(I-362)/T(I-359), but not through D(I-132)/E(I-286), is used for proton transfer to a protonatable group interacting electrostatically with heme a ₃, i.e., upon reduction of the binuclear center. The pathway through D(I-132)/E(I-286) is used for uptake of pumped and substrate protons during the pumping steps during O₂ reduction.     

Cytochrome c Oxidase as a Proton-Pumping Peroxidase: Reaction Cycle and Electrogenic Mechanism

Cytochrome oxidase (COX) is considered to integrate in a single enzyme two consecutive mechanistically different redox activities--oxidase and peroxidase--that can be catalyzed elesewhere by separate hemoproteins. From the viewpoint of energy transduction, the enzyme is essentially a proton pumping peroxidase with a built-in auxiliary eu-oxidase module that activates oxygen and prepares in situ H₂O₂, a thermodynamically efficient but potentially hazardous electron acceptor for the proton pumping peroxidase. The eu-oxidase and peroxidase phases of the catalytic cycle may be performed by different structural states of COX. Resolution of the proton pumping peroxidase activity of COX and identification of individual charge translocation steps inherent in this reaction are discussed, as well as the specific role of the two input proton channels in proton translocation.     

Structural features of [NiFeSe] and [NiFe] hydrogenases determining their different properties: a computational approach

Hydrogenases are metalloenzymes that catalyze the reversible reaction \textH₂ \leftrightarrows 2\textH ⁺ + 2\texte ^- {\text{H}}_{2} \leftrightarrows 2{\text{H}}^{ + } + 2{\text{e}}^{ - } , being potentially useful in H₂ production or oxidation. [NiFeSe] hydrogenases are a particularly interesting subgroup of the [NiFe] class that exhibit tolerance to O₂ inhibition and produce more H₂ than standard [NiFe] hydrogenases. However, the molecular determinants responsible for these properties remain unknown. Hydrophobic pathways for H₂ diffusion have been identified in [NiFe] hydrogenases, as have proton transfer pathways, but they have never been studied in [NiFeSe] hydrogenases. Our aim was, for the first time, to characterize the H₂ and proton pathways in a [NiFeSe] hydrogenase and compare them with those in a standard [NiFe] hydrogenase. We performed molecular dynamics simulations of H₂ diffusion in the [NiFeSe] hydrogenase from Desulfomicrobium baculatum and extended previous simulations of the [NiFe] hydrogenase from Desulfovibrio gigas (Teixeira et al. in Biophys J 91:2035–2045, 2006). The comparison showed that H₂ density near the active site is much higher in [NiFeSe] hydrogenase, which appears to have an alternative route for the access of H₂ to the active site. We have also determined a possible proton transfer pathway in the [NiFeSe] hydrogenase from D. baculatum using continuum electrostatics and Monte Carlo simulation and compared it with the proton pathway we found in the [NiFe] hydrogenase from D. gigas (Teixeira et al. in Proteins 70:1010–1022, 2008). The residues constituting both proton transfer pathways are considerably different, although in the same region of the protein. These results support the hypothesis that some of the special properties of [NiFeSe] hydrogenases could be related to differences in the H₂ and proton pathways.     

Membrane-anchored cytochrome c as an electron carrier in photosynthesis and respiration: past,present and future of an unexpected discovery

In the mid 1980s, it was observed that photosynthesis could still occur in the absence of the diffusible electron carrier cytochrome c ₂ in the purple non-sulfur facultative phototrophic bacterium Rhodobacter capsulatus. This serendipic finding led to the discovery of a novel class of membrane-anchored electron carrier cytochromes and their associated electron transfer pathways. Studies of cytochrome c _y of R. capsulatus (and its homologues in other species) have modified the previous dogma of electron transfer between photosynthetic and respiratory membrane protein complexes with a new paradigm, in which these proteins and their electron carriers can form `hard-wired' structural super-complexes. Here, we reminisce on the early days of this discovery, its impacts on our understanding of cellular energy transduction pathways and the physiological roles played by the electron carrier cytochromes c, and discuss the current knowledge and emerging future challenges of this field. This revised version was published online in August 2006 with corrections to the Cover Date.