Movement of the Rieske iron-sulfur protein in the p-side bulk aqueous phase: effect of lumenal viscosity on redox reactions of the cytochrome b6f complex

Based on the atomic structures of the mitochondrial cytochrome bc(1) complex, it has been proposed that the soluble domain of the [2Fe-2S] Rieske iron-sulfur protein (ISP) must rotate by ca. 60 degrees and translate through an appreciable distance between two binding sites, proximal to cytochrome c(1) and to the lumen-side quinol binding site. Such motional freedom implies that the electron-transfer rate should be affected by the lumenal viscosity. The flash-induced oxidation of cytochrome f, the chloroplast analogue of cytochrome c(1), was found to be inhibited reversibly by increased lumenal viscosity, as was the subsequent reduction of both cytochrome b(6) and cytochrome f. The rates of these three redox reactions correlated inversely with lumenal viscosity over a viscosity range of 1-10 cP. Reduction of cytochrome b(6) and cytochrome f was not concerted. The rate of cytochrome f reduction was observed to be approximately half that of cytochrome b(6) regardless of the actual viscosity, implying that the path length traversed by the ISP in reduction of cytochrome f is twice that of cytochrome b(6). This suggests that upon initiation of electron transfer by a light flash, cytochrome b(6) reduction requires movement of reduced ISP from an initial position predominantly proximal to cytochrome f, apparently favored by the reduced ISP, to the quinol binding site at which the oxidant-induced reduction of cytochrome b(6) is initiated. Subsequent reduction of cytochrome f requires the additional movement of the ISP back to a site proximal to cytochromef. There is no discernible viscosity dependence for cytochrome b(6) reduction under oxidizing conditions, presumably because the oxidized ISP preferentially binds proximal to the quinone binding niche. The dependence of the cytochrome redox reaction on ambient viscosity implies that the tethered diffusional motion of the ISP is part of the rate limitation for charge transfer through the b(6)f complex.     

Steered molecular dynamics simulation of the Rieske subunit motion in the cytochrome bc(1) complex.

Crystallographic structures of the mitochondrial ubiquinol/cytochrome c oxidoreductase (cytochrome bc(1) complex) suggest that the mechanism of quinol oxidation by the bc(1) complex involves a substantial movement of the soluble head of the Rieske iron-sulfur protein (ISP) between reaction domains in cytochrome b and cytochrome c(1) subunits. In this paper we report the results of steered molecular dynamics simulations inducing, through an applied torque within 1 ns, a 56 degrees rotation of the soluble domain of ISP. For this purpose, a solvated structure of the bc(1) complex in a phospholipid bilayer (a total of 206,720 atoms) was constructed. A subset of 91,061 atoms was actually simulated with 45,131 moving atoms. Point charge distributions for the force field parametrization of heme groups and the Fe(2)S(2) cluster of the Rieske protein included in the simulated complex were determined. The simulations showed that rotation of the soluble domain of ISP is actually feasible. Several metastable conformations of the ISP during its rotation were identified and the interactions stabilizing the initial, final, and intermediate positions of the soluble head of the ISP domain were characterized. A pathway for proton conduction from the Q(o) site to the solvent via a water channel has been identified.     

Structure of the soluble domain of cytochrome f from the cyanobacterium Phormidium laminosum.

Cytochrome f from the photosynthetic cytochrome b(6)f complex is unique among c-type cytochromes in its fold and heme ligation. The 1. 9-A crystal structure of the functional, extrinsic portion of cytochrome f from the thermophilic cyanobacterium Phormidium laminosum demonstrates that an unusual buried chain of five water molecules is remarkably conserved throughout the biological range of cytochrome f from cyanobacteria to plants [Martinez et al. (1994) Structure 2, 95-105]. Structure and sequence conservation of the cytochrome f extrinsic portion is concentrated at the heme, in the buried water chain, and in the vicinity of the transmembrane helix anchor. The electrostatic surface potential is variable, so that the surface of P. laminosum cytochrome f is much more acidic than that from turnip. Cytochrome f is unrelated to cytochrome c(1), its functional analogue in the mitochondrial respiratory cytochrome bc(1) complex, although other components of the b(6)f and bc(1) complexes are homologous. Identical function of the two complexes is inferred for events taking place at sites of strong sequence conservation. Conserved sites throughout the entire cytochrome b(6)f/bc(1) family include the cluster-binding domain of the Rieske protein and the heme b and quinone-binding sites on the electrochemically positive side of the membrane within the b cytochrome, but not the putative quinone-binding site on the electrochemically negative side.     

The cytochrome b6f complex. Novel aspects

The Cyt b ₆ f complex from plant chloroplasts, the green alga Chlamydomonas reinhardtii , and the thermophilic cyanobacterium, Mastigocladus laminosus , can be isolated in a highly active state, in which it is dimeric and contains one bound chlorophyll a molecule per monomeric unit. The latter feature is a distinguishing trait compared to the b ₆ f complex of bacterial photosynthesis and the respiratory chain. In contrast to the trans-membrane domains of the b ₆ f complex, and of most other integral membrane proteins, which are characterized by an a -helical structure, the p -side peripheral domains, consisting of Cyt f and the Rieske protein, have a predominantly β-strand secondary structure motif. One consequence of this motif is an extension of these polypeptides from the membrane surface. For example, the length of Cyt f is 75 Å. The heme Fe is 45 Å from the α-carbon of Arg250 at the membrane bilayer interface and, even though Cyt f may be tilted relative to the membrane plane, the heme electron transfer reactions are carried out far from the membrane surface. The presence of an internal 5 water chain, which has the properties of a proton wire, with one water H-bonded to the histidine-25 heme ligand, also suggests that the pathway of long distance H⁺ translocation traverses the extended p -side protein domain of the b ₆ f complex. A mechanism of H⁺ transfer in the chain that is coupled to the redox state of the heme, in which a proton is transferred into the chain to compensate the extra electron in the ferro-heme, is proposed.     

Deuterium kinetic isotope effects in the p-side pathway for quinol oxidation by the cytochrome b(6)f complex.

Plastoquinol oxidation and proton transfer by the cytochrome b(6) f complex on the lumen side of the chloroplast thylakoid membrane are mediated by high and low potential electron transport chains. The rate constant for reduction, k(bred), of cytochrome b(6) in the low potential chain at ambient pH 7.5-8 was twice that, k(fred), of cytochrome f in the high potential chain, as previously reported. k(bred) and k(fred) have a similar pH dependence in the presence of nigericin/nonactin, decreasing by factors of 2.5 and 4, respectively, from pH 8 to an ambient pH = 6, close to the lumen pH under conditions of steady-state photosynthesis. A substantial kinetic isotope effect, k(H2O)/k(D2O), was found over the pH range 6-8 for the reduction of cytochromes b(6) and f, and for the electrochromic band shift associated with charge transfer across the b(6)f complex, showing that isotope exchange affects the pK values linked to rate-limiting steps of proton transfer. The kinetic isotope effect, k(bred)(H2O)/k(bred) (D2O) approximately 3, for reduction of cytochrome b in the low potential chain was approximately constant from pH 6-8. However, the isotope effect for reduction of cytochrome f in the high potential chain undergoes a pH-dependent transition below pH 6.5 and increased 2-fold in the physiological region of the lumen pH, pH 5.7-6.3, where k(fred)(H2O)/k(fred)(D2O) approximately 4. It is proposed that a rate-limiting step for proton transfer in the high potential chain resides in the conserved, buried, and extended water chain of cytochrome f, which provides the exit port for transfer of the second proton derived from p-side quinol oxidation and a "dielectric well" for charge balance.     

Comparison of the cytochrome bc1 complex with the anticipated structure of the cytochrome b6f complex: Le plus ça change le plus c'est la même chose

Structural alignment of the integral cytochrome b6-SU IV subunits with the solved structure of the mitochondrial bc1 complex shows a pronounced asymmetry. There is a much higher homology on the p-side of the membrane, suggesting a similarity in the mechanisms of intramembrane and interfacial electron and proton transfer on the p-side, but not necessarily on the n-side. Structural differences between the bc1 and b6f complexes appear to be larger the farther the domain or subunit is removed from the membrane core, with extreme differences between cytochromes c1 and f. A special role for the dimer may involve electron sharing between the two hemes b(p), which is indicated as a probable event by calculations of relative rate constants for intramonomer heme b(p) --> heme b(n), or intermonomer heme b(p) --> heme b(p) electron transfer. The long-standing observation of flash-induced oxidation of only approximately 0.5 of the chemical content of cyt f may be partly a consequence of the statistical population of ISP bound to cytfon the dimer. It is proposed that the p-side domain of cyt f is positioned with its long axis parallel to the membrane surface in order to: (i) allow its large and small domains to carry out the functions of cyt c1 and suVIII, respectively, of the bc1 complex, and (ii) provide maximum dielectric continuity with the membrane. (iii) This position would also allow the internal water chain ("proton wire") of cyt f to serve as the p-side exit port for an intramembrane H+ transfer chain that would deprotonate the semiquinol located in the myxothiazol/MOA-stilbene pocket near heme b(p). A hypothesis is presented for the identity of the amino acid residues in this chain.     

Interruption of the internal water chain of cytochrome f impairs photosynthetic function

The structure of cytochrome f includes an internal chain of five water molecules and six hydrogen-bonding side chains, which are conserved throughout the phylogenetic range of photosynthetic organisms from higher plants, algae, and cyanobacteria. The in vivo electron transfer capability of Chlamydomonas reinhardtii cytochrome f was impaired in site-directed mutants of the conserved Asn and Gln residues that form hydrogen bonds with water molecules of the internal chain [Ponamarev, M. V., and Cramer, W. A. (1998) Biochemistry 37, 17199-17208]. The 251-residue extrinsic functional domain of C. reinhardtii cytochrome f was expressed in Escherichia coli without the 35 C-terminal residues of the intact cytochrome that contain the membrane anchor. Crystal structures were determined for the wild type and three "water chain" mutants (N168F, Q158L, and N153Q) having impaired photosynthetic and electron transfer function. The mutant cytochromes were produced, folded, and assembled heme at levels identical to that of the wild type in the E. coli expression system. N168F, which had a non-photosynthetic phenotype and was thus most affected by mutational substitution, also had the greatest structural perturbation with two water molecules (W4 and W5) displaced from the internal chain. Q158L, the photosynthetic mutant with the largest impairment of in vivo electron transfer, had a more weakly bound water at one position (W1). N153Q, a less impaired photosynthetic mutant, had an internal water chain with positions and hydrogen bonds identical to those of the wild type. The structure data imply that the waters of the internal chain, in addition to the surrounding protein, have a significant role in cytochrome f function.     

Large-scale purification of active cytochrome b6/f complex from spinach chloroplasts

A preparation is described through which large quantities of pure, active cytochrome b6/f complex can be isolated from spinach chloroplasts. The resulting complex is at least 90% pure with respect to the maximum content of redox centers, consists of four polypeptides according to polyacrylamide gel electrophoresis, and lacks both ferredoxin: NADP+ oxidoreductase and the high molecular weight form of cytochrome f seen in some other preparations. The complex contains 2 mol b6 and 2 atoms of nonheme iron per mole of cytochrome f, and possesses a high plastoquinol-plastocyanin oxidoreductase activity (Cyt f turnover no. 20-35 s-1). The present preparation should be helpful in the effort to crystallize the cytochrome b6/f complex.     

Nearest-neighbor relationships of the constituent polypeptides in plastoquinol-plastocyanin oxidoreductase

The nearest-neighbor relationship among the constituent polypeptides of the isolated plastoquinol-plastocyanin oxidoreductase from spinach chloroplasts has been investigated. (1) The isolated plastoquinol-plastocyanin oxidoreductase (the b6/f complex) is treated with various concentrations of the cross-linker glutaraldehyde. The treated b6/f complexes are then analyzed by SDS-polyacrylamide gel electrophoresis coupled with the immunodecoration of cross-link products by specific antibodies for each of the four prominent constituent polypeptides. Cytochrome b6 is found to be most resistant to forming any intermolecular cross-link products. At low concentrations of glutaraldehyde, the 'Rieske' iron-sulfur (Fe-S) protein and subunit IV of the b6/f complex, however, appear to form cross-link products with a relative molecular weight of 35 000. Dimers of cytochrome f and cytochrome f/Rieske protein cross-link products can also be detected. (2) When a Rieske Fe-S protein-depleted b6/f complex is used in place of the control b6/f complex, cytochrome b6 is less resistant to intermolecular cross-linking, while subunit IV does not form any 35 kDa cross-link product, unlike the case in control b6/f complex. Subunit IV is concluded to be closely associated with the Rieske Fe-S protein. This provides evidence that subunit IV is a bona fide component of the cytochrome b6/f complex, although no function can yet be assigned to it. The results are discussed in relationship to the spatial and functional relationships among the components of the b6/f complex.     

Cytochrome b6f is a dimeric protochlorophyll a binding complex in etioplasts

The cytochrome b6f complex is a dimeric protein complex that is of central importance for photosynthesis to carry out light driven electron and proton transfer in chloroplasts. One molecule of chlorophyll a was found to associate per cytochrome b6f monomer and the structural or functional importance of this is discussed. We show that etioplasts which are devoid of chlorophyll a already contain dimeric cytochrome b6f. However, the phytylated chlorophyll precursor protochlorophyll a, and not chlorophyll a, is associated with subunit b6. The data imply that a phytylated tetrapyrrol is an essential structural requirement for assembly of cytochrome b6f.     

Electron transfer and stability of the cytochrome b6f complex in a small domain deletion mutant of cytochrome f

The lumen segment of cytochrome f consists of a small and a large domain. The role of the small domain in the biogenesis and stability of the cytochrome b(6)f complex and electron transfer through the cytochrome b(6)f complex was studied with a small domain deletion mutant in Chlamydomonas reinhardtii. The mutant is able to grow photoautotrophically but with a slower rate than the wild type strain. The heme group is covalently attached to the polypeptide, and the visible absorption spectrum of the mutant protein is identical to that of the native protein. The kinetics of electron transfer in the mutant were measured by flash kinetic spectroscopy. Our results show that the rate for the oxidation of cytochrome f was unchanged (t(12) = approximately 100 micros), but the half-time for the reduction of cytochrome f is increased (t(12) = 32 ms; for wild type, t(12) = 2.1 ms). Cytochrome b(6) reduction was slower than that of the wild type by a factor of approximately 2 (t(12) = 8.6 ms; for wild type, t(12) = 4.7 ms); the slow phase of the electrochromic band shift also displayed a slower kinetics (t(12) = 5.5 ms; for wild type, t(12) = 2.7 ms). The stability of the cytochrome b(6)f complex in the mutant was examined by following the kinetics of the degradation of the individual subunits after inhibiting protein synthesis in the chloroplast. The results indicate that the cytochrome b(6)f complex in the small domain deletion mutant is less stable than in the wild type. We conclude that the small domain is not essential for the biogenesis of cytochrome f and the cytochrome b(6)f complex. However, it does have a role in electron transfer through the cytochrome b(6)f complex and contributes to the stability of the complex.     

The Cytochrome bc 1 Complex and its Homologue the b 6 f Complex: Similarities and Differences

The ubihydroquinone:cytochrome c oxidoreductase (also called complex III, or bc (1) complex), is a multi subunit enzyme encountered in a very broad variety of organisms including uni- and multi-cellular eukaryotes, plants (in their mitochondria) and bacteria. Most bacteria and mitochondria harbor various forms of the bc (1) complex, while plant and algal chloroplasts as well as cyanobacteria contain a homologous protein complex called plastohydroquinone:plastocyanin oxidoreductase or b (6) f complex. Together, these enzyme complexes constitute the superfamily of the bc complexes. Depending on the physiology of the organisms, they often play critical roles in respiratory and photosynthetic electron transfer events, and always contribute to the generation of the proton motive force subsequently used by the ATP synthase. Primarily, this review is focused on comparing the 'mitochondrial-type' bc (1) complex and the 'chloroplast-type' b (6) f complex both in terms of structure and function. Specifically, subunit composition, cofactor content and assembly, inhibitor sensitivity, proton pumping, concerted electron transfer and Fe-S subunit large-scale domain movement of these complexes are discussed. This is a timely undertaking in light of the structural information that is emerging for the b (6) f complex.     

The single chlorophyll a molecule in the cytochrome b6f complex: unusual optical properties protect the complex against singlet oxygen

The cytochrome b(6)f complex of oxygenic photosynthesis mediates electron transfer between the reaction centers of photosystems I and II and facilitates coupled proton translocation across the membrane. High-resolution x-ray crystallographic structures (Kurisu et al., 2003; Stroebel et al., 2003) of the cytochrome b(6)f complex unambiguously show that a Chl a molecule is an intrinsic component of the cytochrome b(6)f complex. Although the functional role of this Chl a is presently unclear (Kuhlbrandt, 2003), an excited Chl a molecule is known to produce toxic singlet oxygen as the result of energy transfer from the excited triplet state of the Chl a to oxygen molecules. To prevent singlet oxygen formation in light-harvesting complexes, a carotenoid is typically positioned within approximately 4 A of the Chl a molecule, effectively quenching the triplet excited state of the Chl a. However, in the cytochrome b(6)f complex, the beta-carotene is too far (> or =14 Angstroms) from the Chl a for effective quenching of the Chl a triplet excited state. In this study, we propose that in this complex, the protection is at least partly realized through special arrangement of the local protein structure, which shortens the singlet excited state lifetime of the Chl a by a factor of 20-25 and thus significantly reduces the formation of the Chl a triplet state. Based on optical ultrafast absorption difference experiments and structure-based calculations, it is proposed that the Chl a singlet excited state lifetime is shortened due to electron exchange transfer with the nearby tyrosine residue. To our knowledge, this kind of protection mechanism against singlet oxygen has not yet been reported for any other chlorophyll-containing protein complex. It is also reported that the Chl a molecule in the cytochrome b(6)f complex does not change orientation in its excited state.     

Ferredoxin:NADP+ oxidoreductase is a subunit of the chloroplast cytochrome b6f complex

Purified detergent-soluble cytochrome b6f complex from chloroplast thylakoid membranes (spinach) and cyanobacteria (Mastigocladus laminosus) was highly active, transferring 300-350 electrons per cyt f/s. Visible absorbance spectra showed a red shift of the cytochrome f alpha-band and the Qy chlorophyll a band in the cyanobacterial complex and an absorbance band in the flavin 450-480-nm region of the chloroplast complex. An additional high molecular weight (M(r) approximately 35,000) polypeptide in the chloroplast complex was seen in SDS-polyacrylamide gel electrophoresis at a stoichiometry of approximately 0.9 (cytochrome f)(-1). The extra polypeptide did not stain for heme and was much more accessible to protease than cytochrome f. Electrospray ionization mass spectrometry of CNBr fragments of the 35-kDa polypeptide was diagnostic for ferredoxin:NADP+ oxidoreductase (FNR), as were antibody reactivity to FNR and diaphorase activity. The absence of FNR in the cyanobacterial complex did not impair decyl-plastoquinol-ferricyanide activity. The activity of the FNR in the chloroplast b6f complex was also shown by NADPH reduction, in the presence of added ferredoxin, of 0.8 heme equivalents of the cytochrome b6 subunit. It was inferred that the b6f complex with bound FNR, one equivalent per monomer, provides the membrane protein connection to the main electron transfer chain for ferredoxin-dependent cyclic electron transport.     

Epitopes of monoclonal antibodies which inhibit ubiquinol oxidase activity of Escherichia coli cytochrome d complex localize functional domain.

The aerobic respiratory chain of Escherichia coli contains two terminal oxidases: the cytochrome d complex and the cytochrome o complex. Each of these enzymes catalyzes the oxidation of ubiquinol-8 within the cytoplasmic membrane and the reduction of molecular oxygen to water. Both oxidases are coupling sites in the respiratory chain; electron transfer from ubiquinol to oxygen results in the generation of a proton electrochemical potential difference across the membrane. The cytochrome d complex is a heterodimer (subunits I and II) that has three heme prosthetic groups. Previous studies characterized two monoclonal antibodies that bind to subunit I and specifically block the ability of the enzyme to oxidize ubiquinol. In this paper, the epitopes of both of these monoclonal antibodies have been mapped to within a single 11-amino acid stretch of subunit I. The epitope is located in a large hydrophilic loop between the fifth and sixth putative membrane-spanning segments. Binding experiments with these monoclonal antibodies show this polypeptide loop to be periplasmic. Such localization suggests that the loop may be close to His186, which has been identified as one of the axial ligands of cytochrome b558. Together, these data begin to define a functional domain in which ubiquinol is oxidized near the periplasmic surface of the membrane.     

Cytochrome bc complexes: a common core of structure and function surrounded by diversity in the outlying provinces

The atomic-level picture of transmembrane protein complexes in the photosynthetic membrane has now been completed by the recent publication of crystal structures of cytochrome b(6)f and photosystem II. The two structures of cytochrome b(6)f, together with previously reported structures of the cytochrome bc(1) respiratory complex, provide a basis for understanding the central electron and proton transfer events of photosynthesis and respiration. The protein structures and charge transfer events within the core of the complexes are highly similar, but the complexes differ in subunit and chromophore composition in proportion to the distance from the central redox site within the membrane near the electropositive side.     

The structure of the soluble domain of an archaeal Rieske iron-sulfur protein at 1.1 A resolution

The first crystal structure of an archaeal Rieske iron-sulfur protein, the soluble domain of Rieske iron-sulfur protein II (soxF) from the hyperthermo-acidophile Sulfolobus acidocaldarius, has been solved by multiple wavelength anomalous dispersion (MAD) and has been refined to 1.1 A resolution. SoxF is a subunit of the terminal oxidase supercomplex SoxM in the plasma membrane of S. acidocaldarius that combines features of a cytochrome bc(1) complex and a cytochrome c oxidase. The [2Fe-2S] cluster of soxF is most likely the primary electron acceptor during the oxidation of caldariella quinone by the cytochrome a(587)/Rieske subcomplex. The geometry of the [2Fe-2S] cluster and the structure of the cluster-binding site are almost identical in soxF and the Rieske proteins from eucaryal cytochrome bc(1) and b(6)f complexes, suggesting a strict conservation of the catalytic mechanism. The main domain of soxF and part of the cluster-binding domain, though structurally related, show a significantly divergent structure with respect to topology, non-covalent interactions and surface charges. The divergent structure of soxF reflects a different topology of the soxM complex compared to eucaryal bc complexes and the adaptation of the protein to the extreme ambient conditions on the outer membrane surface of a hyperthermo-acidophilic organism.     

The chloroplast ycf7 (petL) open reading frame of Chlamydomonas reinhardtii encodes a small functionally important subunit of the cytochrome b6f complex.

The small chloroplast open reading frame ORF43 (ycf7) of the green unicellular alga Chlamydomonas reinhardtii is cotranscribed with the psaC gene and ORF58. While ORF58 has been found only in the chloroplast genome of C.reinhardtii, ycf7 has been conserved in land plants and its sequence suggests that its product is a hydrophobic protein with a single transmembrane alpha helix. We have disrupted ORF58 and ycf7 with the aadA expression cassette by particle-gun mediated chloroplast transformation. While the ORF58::aadA transformants are indistinguishable from wild type, photoautotrophic growth of the ycf7::aadA transformants is considerably impaired. In these mutant cells, the amount of cytochrome b6f complex is reduced to 25-50% of wild-type level in mid-exponential phase, and the rate of transmembrane electron transfer per b6f complex measured in vivo under saturating light is three to four times slower than in wild type. Under subsaturating light conditions, the rate of the electron transfer reactions within the b6f complex is reduced more strongly in the mutant than in the wild type by the proton electrochemical gradient. The ycf7 product (Ycf7) is absent in mutants deficient in cytochrome b6f complex and present in highly purified b6f complex from the wild-type strain. Ycf7-less complexes appear more fragile than wild-type complexes and selectively lose the Rieske iron-sulfur protein during purification. These observations indicate that Ycf7 is an authentic subunit of the cytochrome b6f complex, which is required for its stability, accumulation and optimal efficiency. We therefore propose to rename the ycf7 gene petL.     

Expression and characterization of the diheme cytochrome c subunit of the cytochrome bc complex in Heliobacterium modesticaldum

Heliobacterium modesticaldum is a Gram-positive, anaerobic, anoxygenic photoheterotrophic bacterium. Its cytochrome bc complex (Rieske/cyt b complex) has some similarities to cytochrome b(6)f complexes from cyanobacteria and chloroplasts, and also shares some characteristics of typical bacterial cytochrome bc(1) complexes. One of the unique factors of the heliobacterial cytochrome bc complex is the presence of a diheme cytochrome c instead of the monoheme cytochrome f in the cytochrome b(6)f complex or the monoheme cytochrome c(1) in the bc(1) complex. To understand the structure and function of this diheme cytochrome c protein, we expressed the N-terminal transmembrane-helix-truncated soluble H. modesticaldum diheme cytochrome c in Escherichia coli. This 25kDa recombinant protein possesses two c-type hemes, confirmed by mass spectrometry and a variety of biochemical techniques. Sequence analysis of the H. modesticaldum diheme cytochrome c indicates that it may have originated from gene duplication and subsequent gene fusion, as in cytochrome c(4) proteins. The recombinant protein exhibits a single redox midpoint potential of +71mV versus NHE, which indicates that the two hemes have very similar protein environments.