Direct electrochemical analyses of human cytochromes <Emphasis Type="Italic">b</Emphasis><Subscript>5</Subscript> with a mutated heme pocket showed a good correlation between their midpoint and half wave potentials

Background  

Cytochrome b ₅ performs central roles in various biological electron transfer reactions, where difference in the redox potential of two reactant proteins provides the driving force. Redox potentials of cytochromes b ₅ span a very wide range of ~400 mV, in which surface charge and hydrophobicity around the heme moiety are proposed to have crucial roles based on previous site-directed mutagenesis analyses.     

The Cytochromes of Prototheca zopfii

The respiratory pigments of Prototheca zopfii include seven cytochromes: two c-type cytochromes, a soluble c(549) and a membrane bound c(551); three b-type cytochromes, b(555), b(559) and b(564); and cytochromes a and a₃. Cytochromes a and a₃ could be resolved spectrally in the α-band region by reducing the cells in the presence of methanol and cyanide. Methanol shifted the absorption maximum of cytochrome a from 598 to 603 nanometers and permitted dithionite (or substrate) to reduce the cyanide-cytochrome a₃ complex to give a well defined 595-nanometer absorption band. Methanol did not interfere with CO binding by cytochrome a₃, and CO did not alter the methanol effect on cytochrome a. Azide and cyanide, which partially inhibited exogenous respiration, stimulated endogenous respiration. Frozen steady states of the electron transport chain in the presence of cyanide and azide indicated that the stimulation by these inhibitors was due to an increased autooxidation of one of the b-type cytochromes, possibly b(564).     

Studies on cytochromes of lichenized fungi under optimized culture conditions

Cytochromes are membrane-bound hemoproteins responsible for the generation of ATP via the electron transport system to fuel the metabolic processes of the organism for their growth. This study reports the properties of cytochromes present in the isolated lichenized fungi of the cultured lichen Usnea ghattensis under optimized conditions. The fungal partner of the cultured lichen Usnea ghattensis contains a, b and c types of cytochromes. The concentrations of a, b and c type cytochromes were found to be significantly high (0.0967, 0.0900, and 0.1030 mM/mg protein, respectively) in the isolated fungal symbiont of cultured lichen grown in malt-yeast extract medium supplemented with 0.01 mol/l sucrose and 0.01 mol/l polyethylglycol. The results suggest that supplementation of additional carbon sources may play a role in optimizing the growth via activating the cytochrome respiratory system in lichenized fungi.     

The electron transport chain ofStreptomyces erythreus: Possible functions of cytochromeaa 3 and a novel green pigment

The cytochromes of the bacteriumStreptomyces erythreus have been investigated. Membrane-bounda-, b-, andc-type cytochromes were found together with a green pigment, which was found in both a soluble and membrane-bound form. Cells containing the green pigment exhibited cyanide-insensitive oxygen uptake. The CO-binding pigments included cytochromea ₃, ab-type cytochrome, cytochrome P450, and the green pigment. Photodissociation spectra at various low temperatures, in the presence or absence of oxygen, revealed cytochromeaa ₃ to be the predominant cytochrome terminal oxidase. The green pigment was capable of electron transport; the relationship of the pigment to the remainder of the electron transport chain remains to be ascertained.     

Cytochromes <Emphasis Type="Italic">c</Emphasis> of the anaerobic methacrylate reducer <Emphasis Type="Italic">Geobacter sulfurreducens</Emphasis> AM-1

Cytochromes c were found in the cells of the bacterium Geobacter sulfurreducens AM-1 grown on acetate and methacrylate. The periplasmic extract of G. sulfurreducens AM-1 contained about 88% of the total content of cytochromes c of intact cells. The analysis of cytochromes c from the native cells of G. sulfurreducens AM-1, from the periplasmic extract and from the cells treated by an alkaline solution showed the presence of nine proteins containing heme c. The molecular masses of cytochromes c from G. sulfurreducens AM-1 were 12.5, 15.5, 25.7, 29.5, 34.7, 41.7, 50.1, 63.1, and 67.6 kDa; localization of each cytochrome c was determined. Three heme-containing proteins (15.5 kDa, 25.7 kDa, and 29.5 kDa with the most intensive staining) were present mainly in the periplasm of the bacterium. The other two (50.1 and 67.6 kDa) were supposedly localized in the cell membrane. Cytochromes c with the molecular masses of 12.5, 15.5, and 67.6 kDa are considered as possible components of the methacrylate redox system of G. sulfurreducens AM-1.     

Purification and characterization of cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript><Emphasis Type="Italic">6</Emphasis></Subscript> from <Emphasis Type="Italic">Acaryochloris marina</Emphasis>

Cytochrome c ₆ , (cyt c ₆) a soluble monoheme electron transport protein, was isolated and characterized from the chlorophyll d-containing cyanobacterium Acaryochoris marina, the type strain MBIC11017. The protein was purified using ammonium sulfate precipitation, ion exchange and gel filtration column chromatography, and fast performance liquid chromatography. Its molecular mass and pI have been determined to be 8.87 kDa and less than 4.2, respectively, by mass spectrometry and isoelectrofocusing (IEF). The protein has an alpha helical structure as indicated by CD (circular dichroism) spectroscopy and a reduction midpoint potential (E _m) of +327 mV versus the normal hydrogen electrode (NHE) as determined by redox potentiometry. Its potential role in electron transfer processes is discussed.     

Purification of Cytochrome a of an L-Glutamate-producing Microorganism,Brevibacterium thiogenitalis

The respiratory chain system of Brev. thiogenitalis grown in the presence of copper ions contained cytochromes a, b and c. The cytochrome a was solubilized and purified from the cell-free extracts by means of Triton X-100 and cholate extraction, and DEAE-cellulose chromatography. It was purified about 130-fold from the cell-free extracts and was free from other cytochromes, The purified preparation contained 1.4 mμatom copper and 1.9 mμatom iron per mμmole heme a, respectively, and approximately 5 mμmoles heme a per mg protein.     

Overexpression, characterization, and crystallization of the functional domain of cytochrome cz from Chlorobium tepidum

Cytochrome c _z is found in green sulfur photosynthetic bacteria, and is considered to be the only electron donor to the special pair P840 of the reaction center. It consists of an N-terminal transmembrane domain and a C-terminal soluble domain that binds a single heme group. Large scale expression of the C-terminal functional domain of the cytochrome c _z (C-cyt c _z) from the thermophilic bacterium Chlorobium tepidum has been achieved using the Escherichia coli expression system. The C-cyt c _z expressed has been highly purified, and is stable at room temperature over 10 days of incubation for both reduced and oxidized forms. Spectroscopic measurements indicate that the heme iron in C-cyt c _z is in a low-spin state and this does not change with the redox state. ¹H-NMR spectra of the oxidized C-cyt c _z exhibited unusually large paramagnetic chemical shifts for the heme methyl protons in comparison with those of other Class I ferric cytochromes c. Differences in the ¹H-NMR linewidth were observed for some resonances, indicating different dynamic environments for these protons. Crystals of the oxidized C-cyt c _z were obtained using ammonium sulfate as a precipitant. The crystals diffracted X-rays to a maximum resolution of 1.2 ?, and the diffraction data were collected to 1.3 ? resolution.     

Cloning,expression, and physicochemical characterization of a new diheme cytochrome <Emphasis Type="Italic">c</Emphasis> from <Emphasis Type="Italic">Shewanella baltica</Emphasis> OS155

The 16-kDa diheme cytochrome c from the bacterium Shewanella baltica OS155 (Sb-DHC) was cloned and expressed in Escherichia coli and investigated through UV–vis, magnetic circular dichroism, and ¹H NMR spectroscopies and protein voltammetry. The model structure was obtained by means of comparative modeling using the X-ray structure of Rhodobacter sphaeroides diheme cytochrome c (Rs-DHC) (with a 37% pairwise sequence identity) as a template. Sb-DHC folds into two distinct domains, each containing one heme center with a bis-His axial ligation. Both secondary and tertiary structures of the N-terminal domain resemble those of class I cytochrome c, displaying three α-helices and a compact overall folding. The C-terminal domain is less helical than the corresponding domain of Rs-DHC. The two heme groups are bridged by Tyr26 in correspondence with the shortest edge-to-edge distance, a feature which would facilitate fast internal electron transfer. The electronic properties of the two prosthetic centers are equivalent and sensitive to two acid–base equilibria with pK _a values of approximately 2.4 and 5, likely corresponding to protonation and detachment of the axial His ligands from the heme iron and a pH-linked conformational change of the protein, respectively. Reduction potentials of −0.144 and −0.257 V (vs. the standard hydrogen electrode), were determined for the C- and N-terminal heme groups, respectively. An approach based on the extended Debye–Hückel equation was applied for the first time to a two-centered metalloprotein and was found to reproduce successfully the ionic strength dependence of E°′.     

Role of multiheme cytochromes involved in extracellular anaerobic respiration in bacteria

Heme containing proteins are involved in a broad range of cellular functions, from oxygen sensing and transport to catalyzing oxidoreductive reactions. The two major types of cytochrome (b‐type and c‐type) only differ in their mechanism of heme attachment, but this has major implications for their cellular roles in both localization and mechanism. The b‐type cytochromes are commonly cytoplasmic, or are within the cytoplasmic membrane, while c‐type cytochromes are always found outside of the cytoplasm. The mechanism of heme attachment allows for complex c‐type multiheme complexes, having the capacity to hold multiple electrons, to be assembled. These are increasingly being identified as secreted into the extracellular environment. For organisms that respire using extracellular substrates, these large multiheme cytochromes allow for electron transfer networks from the cytoplasmic membrane to the cell exterior for the reduction of extracellular electron acceptors. In this review the structures and functions of these networks and the mechanisms by which electrons are transferred to extracellular substrates is described.     

The structure and function of the cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript>2</Subscript>: reaction center electron transfer complex from <Emphasis Type="Italic">Rhodobacter sphaeroides</Emphasis>

In the photosynthetic bacterium, Rhodobacter sphaeroides, the mobile electron carrier, cytochrome c₂ (cyt c₂) transfers an electron from reduced heme to the photooxidized bacteriochlorophyll dimer in the membrane bound reaction center (RC) as part of the light induced cyclic electron transfer chain. A complex between these two proteins that is active in electron transfer has been crystallized and its structure determined by X-ray diffraction. The structure of the cyt:RC complex shows the cyt c₂ (cyt c₂) positioned at the center of the periplasmic surface of the RC. The exposed heme edge from cyt c₂ is in close tunneling contact with the electron acceptor through an intervening bridging residue, Tyr L162 located on the RC surface directly above the bacteriochlorophyll dimer. The binding interface between the two proteins can be divided into two regions: a short-range interaction domain and a long-range interaction domain. The short-range domain includes residues immediately surrounding the tunneling contact region around the heme and Tyr L162 that display close intermolecular contacts optimized for electron transfer. These include a small number of hydrophobic interactions, hydrogen bonds and a pi-cation interaction. The long-range interaction domain consists of solvated complementary charged residues; positively charged residues from the cyt and negatively charged residues from the RC that provide long range electrostatic interactions that can steer the two proteins into position for rapid association.     

Another look at the interaction between mitochondrial cytochrome <Emphasis Type="Italic">c</Emphasis> and flavocytochrome <Emphasis Type="Italic">b</Emphasis><Subscript>2</Subscript>

Yeast flavocytochrome b ₂ tranfers reducing equivalents from lactate to oxygen via cytochrome c and cytochrome c oxidase. The enzyme catalytic cycle includes FMN reduction by lactate and reoxidation by intramolecular electron transfer to heme b ₂. Each subunit of the soluble tetrameric enzyme consists of an N terminal b ₅-like heme-binding domain and a C terminal flavodehydrogenase. In the crystal structure, FMN and heme are face to face, and appear to be in a suitable orientation and at a suitable distance for exchanging electrons. But in one subunit out of two, the heme domain is disordered and invisible. This raises a central question: is this mobility required for interaction with the physiological acceptor cytochrome c, which only receives electrons from the heme and not from the FMN? The present review summarizes the results of the variety of methods used over the years that shed light on the interactions between the flavin and heme domains and between the enzyme and cytochrome c. The conclusion is that one should consider the interaction between the flavin and heme domains as a transient one, and that the cytochrome c and the flavin domain docking areas on the heme b ₂ domain must overlap at least in part. The heme domain mobility is an essential component of the flavocytochrome b ₂ functioning. In this respect, the enzyme bears similarity to a variety of redox enzyme systems, in particular those in which a cytochrome b ₅-like domain is fused to proteins carrying other redox functions.     

Cytochrome b type oxidases in the respiratory chains of the phytopathogenic fluorescent bacteria Pseudomonas cichorii and Pseudomonas aptata

Membrane fragments from the phytopathogenic bacteria Pseudomonas cichorii and Pseudomonas aptata have been examined. A branched respiratory chain is operative in P. cichorii whereas a linear electron transport system characterizes the related bacterium P. aptata. Both species contain several b type cytochromes resolved by redox titration analysis, but no a type components may be detected. In contrast, only P. cichorii is endowed with c type cytochromes and hence with cytochrome c oxidase activity. Among the b type cytochromes, two high-potential components, with Em_7.0 at +250 mV and +380 mV, have been kinetically characterized and tentatively associated with cyanideresistant and cytochrome c oxidase activities, respectively. Cytochrome b-250 should correspond to the spectrally detectable cytochrome o whereas cytochrome b-380 is functionally similar to cytochrome b-410 described in Rhodopseudomonas capsulata. This conclusion seems to blur previous reported data on other obligate aerobes in which cytochrome o has been generally associated with cytochrome c oxidase and also suggests that a more accurate reconsideration of the actual physiological role of cyt. o in bacterial respiration is necessary. Furthermore the question arises whether cyt. b-410 like oxidases, i. e. high-potential b's similar to cyt. b-410 of R. capsulata, may be widely distributed among aerobes rather than restricted to facultative photosynthetic prokaryotes.     

Sulfide-quinone reductase activity in membranes of the chemotrophic bacterium Paracoccus denitrificans GB17

Reduction of exogenous ubiquinone and of cytochromes by sulfide in membranes of the chemotrophic bacterium Paracoccus denitrificans GB17 was studied. For sulfide-ubiquinone reductase activity, K _m values of 26 ± 4 and 3.1 ± 0.6 μM were determined from titrations with sulfide and decyl-ubiquinone, respectively. A maximal rate of up to 0.3 μmol decyl-ubiquinone reduced (mg protein)^–1 min^–1 was estimated. The reaction was sensitive to quinone-analogous inhibitors, but insensitive to cyanide. Reduction of cytochromes by sulfide was monitored with an LED-array spectrophotometer. Under oxic conditions, reduction rates and extents of reduction were lower than those under anoxic conditions. Reoxidation of cytochromes was oxygen-dependent and cyanide-sensitive. The multiphasic behavior of transient reduction of cytochrome b with limiting amounts of sulfide reflects that sulfide, in addition to acting as an electron donor, is a slowly binding inhibitor of cytochrome c oxidase. The initial peak of cytochrome b reduction is dependent on electron flow to an oxidant, either oxygen or ferricyanide, and is stimulated by antimycin A. This oxidant-induced reduction of cytochrome b suggests that electron transport from sulfide in P. denitrificans GB17 employs the cytochrome bc ₁ complex via the quinone pool. Received: 8 April 1998 / Accepted: 29 July 1998     

Proline Rich Polypeptide (PRP-1) Increases the Superoxide-Producing and Ferrihemoglobin Reducing Activities of Cytochrome B<Subscript>558</Subscript> Isoforms from Human Lymphosarcoma Tissue Cells

The two cytochromes (cyt) b₅₅₈ of acidic nature, one—95–100 kDa and another one, 60–70 kDa were isolated for the first time from the human’s lymphosarcoma tissue cells using gel filtration and ion exchange chromatography. These hemoproteins possess NADPH dependent O₂ ⁻-producing and ferrihemoglobin-reducing activities. The incubation of neuropeptide PRP-1 (5 μg) with cytochrome b₅₅₈, caused elevation of these activities. The gel filtration results indicated possible binding of PRP-1 to these cytochromes b₅₅₈. PRP-1 activated both NADPH dependent O₂ ⁻-producing and ferriHb-reducing activities of the cyt b¹ ₅₅₈ and cyt b² ₅₅₈, obtained from human lymphosarcoma tissue cells. One can assume that PRP-1 associated with cyt b₅₅₈ on the surface of the tumor cells by increasing both NADPH dependent O₂ ⁻-producing and ferriHb-reducing activities of cyt b₅₅₈, increases the oxidation- reduction status. Changing the oxidation–reduction status and oxygen homeostasis of the tumor cells by PRP-1 can serve as one of the possible explanation of antitumorigenic effect of this cytokine.     

Purification and biochemical properties of a cytochrome <Emphasis Type="Italic">bc</Emphasis> complex from the aerobic hyperthermophilic archaeon <Emphasis Type="Italic">Aeropyrum pernix</Emphasis>

Background  

The bioenergetics of Archaea with respect to the evolution of electron transfer systems is very interesting. In contrast to terminal oxidases, a canonical bc ₁ complex has not yet been isolated from Archaea. In particular, c -type cytochromes have been reported only for a limited number of species.     

Molecular modeling of cytochrome b₅ with a single cytochrome c-like thioether linkage

Bovine liver cytochrome b ₅ (cyt b ₅), with heme bound noncovalently, has been converted into a cyt c-like protein (cyt b ₅ N57C) by constructing a thioether linkage between the heme and the engineered cysteine residue. With no X-ray or NMR structure available, we herein performed a molecular modeling study of cyt b ₅ N57C. On the other hand, using amino acid sequence information for a newly discovered member of the cyt b ₅ family, domestic silkworm cyt b ₅ (DS cyt b ₅), we predicted the protein structure by homology modeling in combination with MD simulation. The modeling structure shows that both Cys57 in cyt b ₅ N57C, and Cys56, a naturally occurring cysteine in DS cyt b ₅, have suitable orientations to form a thioether bond with the heme 4-vinyl group, as the heme is in orientation A. In addition to providing structural information that was not previously obtained experimentally, these modeling studies provide insight into the formation of cyt c-like thioether linkages in cytochromes, and suggest that c-type cyt b ₅ maturation involves a b-type intermediate.     

Role of Copper Ions in the Regulation of L-Glutamate Biosynthesis

Cell-free extracts of Brevibacterium thiogenitalis culture grown in the presence of copper catalyzed the oxidation of NADH₂ and succinate through an electron transport chain which contained menaquinones and cytochromes a, b and c. On the other hand, extracts of cells grown in the absence of copper lacked cytochromes a and c, and contained cytochrome d.

These findings, as well as the results obtained in inhibition experiments, suggest that in copper-deficient cells the major part of NADH₂ was oxidized via a bypass in which the electrons were transferred directly from flavoprotein or cytochrome b to molecular oxygen.

Electron transport from these substrates to molecular oxygen resulted in ATP synthesis. The average P/O ratios in extracts of the copper-sufficient cells were 0.33 for generated NADH₂, 0.20 for added NADH₂, and 0.34 for succinate, and those in extracts of the copper-deficient cells were 0.15, 0.13 and 0.21, respectively. In addition, a linear relationship was found between the yield of L-glutamate from acetate and the P/Ο ratios with both NADH₂ and succinate as substrates.

From these results, it is reasonable to consider that the poor yield of L-glutamate from acetate in copper-deficient cells was due to a reduction in energy supply, which was caused by the low efficiency of oxidative phosphorylation.     

Maturation of a eukaryotic cytochrome <Emphasis Type="Italic">c</Emphasis> in the cytoplasm of <Emphasis Type="Italic">Escherichia coli</Emphasis> without the assistance by a dedicated biogenesis apparatus

Maturation of c-type cytochromes involves the covalent and stereospecific enzymatic attachment of a heme b via thioether linkages to two conserved cysteines within apocytochromes. Horse cytochrome c is readily matured into its native holoform in the cytoplasm of E. coli when co-expressed with yeast cytochrome c heme lyase. Here we report the low yield formation of holocytochrome with covalently attached heme also in the absence of heme lyase. This is the first demonstration of in vivo maturation of a eukaryotic cytochrome c in a prokaryotic cytoplasm without the assistance by a dedicated enzymatic maturation system. The assembled cytochrome c can be oxidized by cytochrome c oxidase, indicating the formation of a functional protein. The absorption spectrum is typical of a low spin, six coordinated c-type heme. Nevertheless, minor spectral differences relative to the native cytochrome c, deviation of the midpoint reduction potential and slightly altered kinetic parameters of the interaction with cytochrome c oxidase emphasize the importance of cytochrome c heme lyase in folding cytochrome c into its native conformation.     

The Respiratory Chain of Plant Mitochondria: XII. Some Aspects of the Energy-linked Reverse Electron Transport from the Cytochromes c to the Cytochromes b in Mung Bean Mitochondria

The cytochromes c of mung bean (Phaseolus aureus) mitochondria become reduced when sulfide, a cytochrome oxidase inhibitor free from uncoupling side effects, is added to the aerobic mitochondrial suspension in the absence of added substrate. The cytochromes b remain largely oxidized. Subsequent addition of ATP results in partial oxidation of the cytochromes c and partial reduction of the cytochromes b due to ATP-driven reverse electron transport through the second site of energy conservation, or coupling site, of the respiratory chain. Cytochrome a is also oxidized under these conditions, but there is no concomitant reduction of the flavoprotein components, of ubiquinone, or of endogenous pyridine nucleotide. The reaction is abolished by oligomycin. The reducing equivalents transported from the cytochromes c and a in ATP-driven reverse electron transport are about 2-fold greater than those which appear in the cytochromes b. It is suggested that the equivalents not accounted for are present in a coupling site enzyme at the second site of energy conservation which interacts with the respiratory chain carriers by means of the dithiol-disulfide couple; this couple would not show absorbance changes with redox state over the wavelength range examined. With succinate present, reverse electron transport can be demonstrated at both coupling sites in both the aerobic steady state and in anaerobiosis. ATP-driven reverse electron transport in anaerobiosis maintains cytochrome a 30% oxidized while endogenous pyridine nucleotide is 50% reduced.