Site-directed mutagenesis of tetraheme cytochrome c3. Modification of oxidoreduction potentials after heme axial ligand replacement.

The nature of the axial ligands of a heme group is an important factor in maintaining the oxidation-reduction potential of a c-type cytochrome. Cytochrome c3 from Desulfovibrio vulgaris Hildenborough contains four bis-histidinyl coordinated hemes with low oxidation-reduction potentials. Site-directed mutagenesis was used to generate a mutant in which histidine 70, the sixth axial ligand of heme 4, has been replaced by a methionine. The mutant protein was expressed in Desulfovibrio desulfuricans G200 at a level similar to the wild type cytochrome. A model for the three-dimensional structure of D. vulgaris Hildenborough cytochrome c3 was generated on the basis of the crystal structure of D. vulgaris Miyazaki cytochrome c3 in order to investigate the effects of the H70M mutation. The model, together with NMR data, suggested that methionine 70 has effectively replaced histidine 70 as the sixth axial ligand of heme 4 without significant alteration of the structure. A large increase of at least 200 mV of one of the four oxidation-reduction potentials was observed by electrochemistry and is interpreted in terms of structure/potential relationships.     

Photoacoustic characterization of protein dynamics following CO photodetachment from fully reduced bovine cytochrome c oxidase

We report a protein conformational change following carbon monoxide photodetachment from fully reduced bovine cytochrome c oxidase that is hypothesized to be associated with changes in ligand mobility through a dioxygen access channel in the protein. Although not resolved by earlier photoacoustic or optical studies on this adduct, utilization of slightly lower temperatures revealed a process with a kinetic lifetime of about 70 ns at 10 degrees C. We measure an enthalpy change of about 8 kcal/mol in 0.050 M HEPES buffer that becomes less endothermic (DeltaH approximately 2 kcal/mol) at higher ionic strength. The volume contraction of about -0.7 mL/mol associated with the process almost doubles in higher ionic strength buffer systems. Measurements of samples in phosphate buffer systems are similar and appear to display the same subtle ionic strength dependence. Both the isolation of this photoacoustic signal component and the possible dependence on ionic strength of the thermodynamic parameters derived from its analysis appear analogous to and consistent with prior photoacoustic results monitoring CO photodetachment from the camphor complex of cytochrome P-450. Accordingly, we consider a similar model in which a conformational change results in movement of an exposed charged group or groups towards the interior of the protein, out of contact with solvent, as in the closing of a salt bridge.     

The comparative study on the solution structures of the oxidized bovine microsomal cytochrome b5 and mutant V45H

A comparative study on the solution structures of bovine microsomal cytochrome b5 (Tb5) and the mutant V45H has been achieved by 1D and 2D 1H-NMR spectroscopy to clarify the differences in the solution conformations between these two proteins. The results reveal that the global folding of the V45H mutant in solution is unchanged, but the subtle changes exist in the orientation of the axial ligand His39, and heme vinyl groups. The side chain of His45 in V45H mutant extends to the outer edge of the heme pocket leaving a cavity at the site originally occupied by the inner methyl group of Val45 residue. In addition, the imidazole ring of axial ligand His39 rotates counterclockwise by approximately 3 degrees around the His-Fe-His axis, and the 4-heme vinyl group turns to the space vacated by the removed side chain due to the mutation. Furthermore, the helix III of the heme pocket undergoes outward displacement, while the linkage between helix II and III is shifted leftward. These observations are not only consistent with the pattern of the pseudocontact shifts of the heme protons, but also well account for the lower stability of V45H mutant against heat and urea.     

Effects of tryptophan microenvironment, soluble domain, and vesicle size on the thermodynamics of membrane protein folding: lessons from the transmembrane protein OmpA

Refolding curves of the integral membrane protein outer membrane protein A (OmpA) were measured to determine the conformational stabilities of this model system for membrane protein folding. Wild-type OmpA exhibits a free energy of unfolding (DeltaG degrees H2O) of 10.5 kcal/mol. Mutants, containing a single tryptophan residue at the native positions 7, 15, 57, 102, or 143, are less stable than wild-type OmpA, with DeltaG degrees H2O values of 6.7, 4.8, 2.4, 4.7, and 2.8 kcal/mol, respectively. The trend observed here is discussed in terms of noncovalent interactions, including aromatic interactions and hydrogen bonding. The effect of the soluble tail on the conformational stability of the transmembrane domain of OmpA was also investigated via truncated single-Trp mutants; DeltaG degrees H2O values for four of the five truncated mutants are greater by >2.7 kcal/mol relative to the full-length versions, suggesting that the absence of the soluble domain may destabilize the unfolded transmembrane domain. Finally, dynamic light scattering experiments were performed to measure the effects of urea and protein on vesicle size and stability. Urea concentrations greater than 1 M cause an increase in vesicle size, and these diameters are unaltered in the presence of protein. These dynamic light scattering results complement the fluorescence studies and illustrate the important effects of vesicle size on protein conformational stability.     

Stabilization of Escherichia coli ribonuclease H by introduction of an artificial disulfide bond.

To examine the effect of the introduction of a disulfide bond on the stability of Escherichia coli ribonuclease H, a disulfide bond was engineered between Cys13, which is present in the wild-type enzyme, and Cys44, which is substituted for Asn44 by site-directed mutagenesis. The disulfide bond was only formed between these residues upon oxidation in vitro with redox buffer. The conformational and thermal stabilities were estimated from the guanidine hydrochloride and thermal denaturation curves, respectively. The oxidized (cross-linked) mutant enzyme showed a Tm of 62.3 degrees C, which was 11.8 degrees C higher than that observed for the wild-type enzyme. The free energy change of unfolding in the absence of denaturant, delta G[H2O], and the mid-point of the denaturation curve, [D]1/2, of the oxidized mutant enzyme were also increased by 2.1-2.8 kcal/mol and 0.36-0.48 M, respectively. Introduction of a disulfide bond thus greatly enhanced both the thermal and conformational stabilities of the enzyme. In addition, kinetic analyses for the enzymatic activities of mutant enzymes suggest that Thr43 and Asn44 are involved in the substrate-binding site of the enzyme.     

Contribution of conformational stability and reversibility of unfolding to the increased thermostability of human and bovine superoxide dismutase mutated at free cysteines

The conformational stability and reversibility of unfolding of the human dimeric enzyme Cu Zn superoxide dismutase (HSOD) and the three mutant enzymes constructed by replacement of Cys6 by Ala and Cys111 by Ser, singly and in combination, were determined by differential scanning calorimetry. The differential scanning calorimetry profile of wild-type HSOD consists of two components, which probably represent the unfolding of the oxidized and reduced forms of the enzyme, with denaturation temperatures (Tm) of 74.9 and 83.6 degrees C, approximately 7 degrees lower than those for bovine superoxide dismutase (BSOD). The conformational stabilities of the two components of the mutant HSOD's differ only slightly from those of the wild type (delta delta Gs of -0.2 to +0.8 kcal/mol of dimer), while replacement of the BSOD Cys6 by Ala is somewhat destabilizing (delta delta G of -0.7 to -1.3 kcal/mol of dimer). These small alterations in conformational stability do not correlate with the large increases in resistance to thermal inactivation following substitution of free Cys in both HSOD and BSOD (McRee, D.E., Redford, S.M., Getzoff, E.D., Lepock, J.R., Hallewell, R.A., and Tainer, J.A. (1990) J. Biol. Chem. 265, 14234-14241 and Hallewell, R.A., Imlay, K.C., Laria, I., Gallegos, C., Fong, N., Irvine, B., Getzoff, E.D., Tainer, J.A., Cubelli, D.E., Bielski, B.H.J., Olson, P., Mallenbach, G.T., and Cousens, L.S. (1991) Proteins Struct. Funct. Genet., submitted for publication). The reversibility of unfolding was determined by scanning part way through the profile, cooling, rescanning, and calculating the amount of protein irreversibly unfolded by the first scan. The order of reversibility at a constant level of unfolding is the same as the order of resistance to inactivation for both the HSOD and BSOD wild-type and mutant enzymes. Thus, the greater resistance to thermal inactivation of the superoxide dismutase enzymes with free Cys replaced by Ala or Ser is dominated by a greater resistance to irreversible unfolding and relatively unaffected by changes in conformational stability.     

Effect of pH on axial ligand coordination of cytochrome c" from Methylophilus methylotrophus and horse heart cytochrome c

The effect of protons on the axial ligand coordination and on structural aspects of the protein moiety of cytochrome c' ' from Methylophilus methylotrophus, an obligate methylotroph, has been investigated down to very low pH (i.e., 0.3). The unusual resistance of this cytochrome to very low pH values has been exploited to carry out this study in comparison with horse heart cytochrome c. The experiments were undertaken at a constant phosphate concentration to minimize the variation of ionic strength with pH. The pH-linked effects have been monitored at 23 degrees C in the oxidized forms of both cytochromes by following the variations in the electronic absorption, circular dichroism and resonance Raman spectra. This approach has enabled the conformational changes of the heme surroundings to be monitored and compared with the concomitant overall structural rearrangements of the molecule. The results indicate that horse heart cytochrome c undergoes a first conformational change at around pH 2.0. This event is possibly related to the cleavage of the Fe-Met80 bond and a likely coordination of a H(2)O molecule as a sixth axial ligand. Conversely, in cytochrome c" from M. methylotrophus, a variation of the axial ligand coordination occurs at a pH that is about 1 unit lower. Further, it appears that a concerted cleavage of both His ligands takes place, suggesting indeed that the different axial ligands present in horse heart cytochrome c (Met/His) and in cytochrome c" from M. methylotrophus (His/His) affect the heme conformational changes.     

Resilience of Rhodobacter sphaeroides cytochrome bc1 to heme c1 ligation changes

Typically, c hemes are bound to the protein through two thioether bonds to cysteines and two axial ligands to the heme iron. In high-potential class I c-type cytochromes, these axial ligands are commonly His-Met. A change in this methionine axial ligand is often correlated with a dramatic drop in the heme redox potential and loss of function. Here we describe a bacterial cytochrome c with an unusual tolerance to the alternations in the heme ligation pattern. Substitution of the heme ligating methionine (M185) in cytochrome c1 of the Rhodobacter sphaeroides cytochrome bc1 complex with Lys and Leu lowers the redox midpoint potential but not enough to prevent physiologically competent electron transfer in these fully functional variants. Only when Met-185 is replaced with His is the drop in the redox potential sufficiently large to cause cytochrome bc1 electron transfer chain failure. Functional mutants preserve the structural integrity of the heme crevice: only the nonfunctional His variant allows carbon monoxide to bind to reduced heme, indicating a significant opening of the heme environment. This range of cytochrome c1 ligand mutants exposes both the relative resilience to sixth axial ligand change and the ultimate thermodynamic limits of operation of the cofactor chains in cytochrome bc1.     

Effect of chaotropic agents on reversible unfolding of a soybean (Glycine max) seed acid phosphatase

In this work we examined the effect of urea and guanidinium chloride on the structural stability of a single isoform of soybean seed acid phosphatase, based on the intensity of tryptophan fluorescence as a function of denaturant concentration. The free energy of unfolding, DeltaGu, was calculated at 25 degrees C as a function of the concentrations of both chaotropic agents; the conformational stability, DeltaG (H2O), was determined to be 2.48 kcal mol(-1). Center of mass, determined from analysis of fluorescence data, was used as a parameter to assess conformational changes. Our results indicate that complete enzyme inactivation occurred before full enzyme unfolding in both cases, and suggest that there are differences between the conformational flexibility of the active-site and that of the macromolecule as a whole.     

The distinct heme coordination environments and heme-binding stabilities of His39Ser and His39Cys mutants of cytochrome b5

A gene mutant library containing 16 designed mutated genes at His39 of cytochrome b(5) has been constructed by using gene random mutagenesis. Two variants of cytochrome b(5), His39Ser and His39Cys mutant proteins, have been obtained. Protein characterizations and reactions were performed showing that these two mutants have distinct heme coordination environments: ferric His39Ser mutant is a high-spin species whose heme is coordinated by proximal His63 and likely a water molecule in the distal pocket, while ferrous His39Ser mutant has a low-spin heme coordinated by His63 and Ser39; on the other hand, the ferric His39Cys mutant is a low-spin species with His63 and Cys39 acting as two axial ligands of the heme, the ferrous His39Cys mutant is at high-spin state with the only heme ligand of His63. These two mutants were also found to have quite lower heme-binding stabilities. The order of stabilities of ferric proteins is: wild-type cytochrome b(5) > His39Cys > His39Ser.     

Proximal cysteine residue is essential for the enzymatic activities of cytochrome P450cam.

To investigate the functional and structural roles of the proximal thiolate ligand in cytochrome P450cam, we prepared the C357H mutant of the enzyme in which the axial cysteine residue (Cys357) was replaced with a histidine residue. We obtained the unstable C357H mutant by developing a new preparation procedure involving in vitro folding of P450cam from the inclusion bodies. The C357H mutant in the ferrous-CO form exhibited the Soret peak at 420 nm and the Fe-CO stretching line at 498 cm-1, indicating a neutral histidine residue as the axial ligand. However, another internal ligand is coordinated to the heme iron as the sixth ligand in the ferric and ferrous forms of the C357H mutant, suggesting the collapse of the substrate-binding site. The C357H mutant showed no catalytic activity for camphor hydroxylation and the reduced heterolytic/homolytic ratio of the O-O bond scission in the reaction with cumene hydroperoxide. The present observations indicate that the thiolate coordination in P450cam is important for the construction of the heme pocket and the heterolysis of the O-O bond.     

Expression, mutagenesis, and characterization of recombinant low-potential cytochrome c550 of photosystem II

Cytochrome c(550) of the photosystem II complex of cyanobacteria is an unusual member of the large protein family of monoheme c-type cytochromes. Despite the fact that it shares considerable amino acid sequence similarity and has a protein fold similar to the other members of the family, Cyt.c(550) has a midpoint potential (E(m7) = -250 mV) that is much lower than the positive midpoint potentials characteristic (E(m7) = 100-300mV) of this cytochrome family. An E. coli heterologous expression system involving secretion of the recombinant protein from Synechocystis PCC6803 to the periplasm was utilized to allow production of wild-type and mutant forms of the cytochrome. For most of the variants studied, the yield of protein was significantly enhanced by growth at 28 degrees C and inclusion of sucrose and betaine, in addition to isopropyl-beta-d-thiogalactoside (IPTG), to the growth medium of the E. coli expression host. Analysis of the protein products revealed that the wild-type protein maintained the redox and visible spectroscopic characteristics of the authentic protein. Mutations in the residues engaging in hydrogen bond interactions with the heme propionate (Asn49) and the axial 6th ligand His92 (Pro93) resulted in small (12-20 mV), but reproducible, upshifts in midpoint redox potential. Substitution of the axial ligand His92 with Met produced no discernible changes in the optical spectrum relative to the wild-type despite the fact that in this mutant, unlike the others studied here, the thioether linkage either was not formed or was highly labile as evidenced by loss of the heme during SDS-PAGE. On the other hand, the midpoint potential of the C550-H92M mutant was upshifted by approximately 70 mV. This value is significantly less of a perturbation than that observed in a similar mutant that is natively expressed in Thermosynechoccocus but appears to have an intact thioether linkage between the heme and the polypeptide moiety.     

Converting a c-type to a b-type cytochrome: Met61 to His61 mutant of Pseudomonas cytochrome c-551

The gene nirM, coding for cytochrome c-551 in Pseudomonas stutzeri substrain ZoBell, was engineered to mutate Met61, the sixth ligand to the heme c, into His61, thereby converting the typical Met-His coordination of a c-type cytochrome into His-His, typical of b-type cytochromes. The mutant protein was expressed heterologously in Escherichia coli at levels 3-fold higher than in Pseudomonas and purified to homogeneity. The mutant retained low-spin visible spectral characteristics, indicating that the strong field ligand His 61 was coordinated to the iron. The physiochemical properties of the mutant were measured and compared to the wild-type properties. These included visible spectra, ligand binding reactions, stability to temperature and chemical denaturant, oxidation-reduction potentials, and electron-transfer kinetics to the physiological nitrite reductase of Pseudomonas. Despite a change in potential from the normal 260 mV to 55 mV, the mutant retained many of the properties of the c-551 family.     

Protein dynamics: imidazole and 2-mercaptoethanol binding to the Rhodobacter capsulatus cytochrome c(2) mutant,glycine 95 proline

The Class I c-type cytochromes can bind exogenous ligands in the oxidized state, with the kinetics of ligand binding providing information on naturally occurring intramolecular dynamics. Typically, nitrogenous bases are used as ligands; however, it is less well known that 2-mercaptoethanol (BME), a commonly used cytochrome reducing agent, can form a complex with the heme. To better understand the cytochrome-mercaptan interaction, we have investigated the kinetics of binding of BME to wild type and mutants of Rhodobacter capsulatus cytochrome c(2) and to horse cytochrome c. Complex formation with the G95P mutant is apparent from the formation of a green color and a shift in the Soret peak to 418 nm from 410 nm upon addition of BME. Unlike horse cytochrome c and wild-type R. capsulatus cytochrome c(2), G95P permits the kinetics of formation of the BME-G95P complex to be measured since complex formation and reduction kinetics can be resolved. The affinity constant for the binding of BME to mutant G95P was strong ( approximately 1.5 x 10(5)M(-1)) and the kinetics of formation of the BME-G95P complex were found to undergo a change in rate-limiting step consistent with a concentration-independent protein rearrangement (68s(-1)) followed by second-order binding of BME ( approximately approximately 1.3 x 10(5)M(-1)s(-1)). The most remarkable characteristic of mutant G95P is the relatively large amount of high-spin species in equilibrium with the low- spin form, which can be estimated to be approximately 3% at pH 7. The BME binding kinetics, coupled with the kinetics of imidazole binding to G95P, allow us, for the first time, to specify all four rate constants describing the ligand binding reaction. Moreover, we can use the kinetic results to estimate the rate constants for ligand binding with the wild-type cytochrome c(2). This has also allowed us to quantify and more fully interpret cytochrome dynamics.     

Relationship between local and global stabilities of proteins: site-directed mutants and chemically-modified derivatives of cytochrome c.

The methionine 80 sulfur-heme iron bond of rat cytochrome c, whose stability is decreased by mutating the phylogenetically invariant residue proline 30 to alanine and increased when tyrosine 67 is changed to phenylalanine, recovers its wild-type characteristics when both substitutions are performed on the same molecule. Titrations with urea, analyzed according to the heteropolymer theory [Alonso, D. O. V., & Dill, K. A. (1991) Biochemistry 30, 5974-5985], indicate that both single mutations increase the solvent exposure of hydrophobic groups in the unfolded state, while in the double mutant this conformational perturbation disappears. Similar increases in solvent exposure of hydrophobic groups are observed when the sulfur-iron bond of the wild-type protein is broken by alkylation of the methionine sulfur, by high pH, or by binding the heme iron with cyanide. The compensatory effects of the two single mutations do not extend to the overall stability of the protein. The added loss of conformational stability due to the single mutations amounts to 7.3 kcal/mol out of the 9 kcal/mol representing the overall free energy of stabilization of the native conformation of the wild-type protein. The folded conformation of the doubly mutated protein is only 2 kcal/mol less stable than that of the wild type. These results indicate that the double mutant protein is able to retain the essential folding pattern of cytochrome c and the thermodynamic stability of the methionine sulfur-heme iron bond, in spite of structural differences that weaken the overall stability of the molecule.     

Stability enhancement of cytochrome c through heme deprotonation and mutations

The chemical denaturation of Pseudomonas aeruginosa cytochrome c(551) variants was examined at pH 5.0 and 3.6. All variants were stabilized at both pHs compared with the wild-type. Remarkably, the variants carrying the F34Y and/or E43Y mutations were more stabilized than those having the F7A/V13M or V78I ones at pH 5.0 compared with at pH 3.6 by ~3.0-4.6 kJ/mol. Structural analyses predicted that the side chains of introduced Tyr-34 and Tyr-43 become hydrogen donors for the hydrogen bond formation with heme 17-propionate at pH 5.0, but less efficiently at pH 3.6, because the propionate is deprotonated at the higher pH. Our results provide an insight into a stabilization strategy for heme proteins involving variation of the heme electronic state and introduction of appropriate mutations.     

Spectroscopic and oxidation-reduction properties of Rhodobacter capsulatus cytochrome c1 and its M183K and M183H variants

Two variants of the cytochrome c1 component of the Rhodobacter capsulatus cytochrome bc1 complex, in which Met183 (an axial heme ligand) was replaced by lysine (M183K) or histidine (M183H), have been analyzed. Electron paramagnetic resonance (EPR) and magnetic circular dichroism (MCD) spectra of the intact complex indicate that the histidine/methionine heme ligation of the wild-type cytochrome is replaced by histidine/lysine ligation in M183K and histidine/histidine ligation in M183H. Variable amounts of histidine/histidine axial heme ligation were also detected in purified wild-type cytochrome c1 and its M183K variant, suggesting that a histidine outside the CSACH heme-binding domain can be recruited as an alternative ligand. Oxidation-reduction titrations of the heme in purified cytochrome c1 revealed multiple redox forms. Titrations of the purified cytochrome carried out in the oxidative or reductive direction differ. In contrast, titrations of cytochrome c1 in the intact bc1 complex and in a subcomplex missing the Rieske iron-sulfur protein were fully reversible. An Em7 value of -330 mV was measured for the single disulfide bond in cytochrome c1. The origins of heme redox heterogeneity, and of the differences between reductive and oxidative heme titrations, are discussed in terms of conformational changes and the role of the disulfide in maintaining the native structure of cytochrome c1.     

Strategic roles of axial histidines in structure formation and redox regulation of tetraheme cytochrome c3

Tetraheme cytochrome c 3 (cyt c 3) exhibits extremely low reduction potentials and unique properties. Since axial ligands should be the most important factors for this protein, every axial histidine of Desulfovibrio vulgaris Miyazaki F cyt c 3 was replaced with methionine, one by one. On mutation at the fifth ligand, the relevant heme could not be linked to the polypeptide, revealing the essential role of the fifth histidine in heme linking. The fifth histidine is the key residue in the structure formation and redox regulation of a c-type cytochrome. A crystal structure has been obtained for only H25M cyt c 3. The overall structure was not affected by the mutation except for the sixth methionine coordination at heme 3. NMR spectra revealed that each mutated methionine is coordinated to the sixth site of the relevant heme in the reduced state, while ligand conversion takes place at hemes 1 and 4 during oxidation at pH 7. The replacement of the sixth ligand with methionine caused an increase in the reduction potential of the mutated heme of 222-244 mV. The midpoint potential of a triheme H52M cyt c 3 is higher than that of the wild type by approximately 50 mV, suggesting a contribution of the tetraheme architecture to the lowering of the reduction potentials. The hydrogen bonding of Thr24 with an axial ligand induces a decrease in reduction potential of approximately 50 mV. In conclusion, the bis-histidine coordination is strategically essential for the structure formation and the extremely low reduction potential of cyt c 3.     

The redox couple of the cytochrome c cyanide complex: the contribution of heme iron ligation to the structural stability, chemical reactivity, and physiological behavior of horse cytochrome c

Contrary to most heme proteins, ferrous cytochrome c does not bind ligands such as cyanide and CO. In order to quantify this observation, the redox potential of the ferric/ferrous cytochrome c-cyanide redox couple was determined for the first time by cyclic voltammetry. Its E0' was -240 mV versus SHE, equivalent to -23.2 kJ/mol. The entropy of reaction for the reduction of the cyanide complex was also determined. From a thermodynamic cycle that included this new value for the cyt c cyanide complex E0', the binding constant of cyanide to the reduced protein was estimated to be 4.7 x 10(-3) L M(-1) or 13.4 kJ/mol (3.2 kcal/mol), which is 48.1 kJ/mol (11.5 kcal/mol) less favorable than the binding of cyanide to ferricytochrome c. For coordination of cyanide to ferrocytochrome c, the entropy change was earlier experimentally evaluated as 92.4 J mol(-1) K(-1) (22.1 e.u.) at 25 K, and the enthalpy change for the same net reaction was calculated to be 41.0 kJ/mol (9.8 kcal/mol). By taking these results into account, it was discovered that the major obstacle to cyanide coordination to ferrocytochrome c is enthalpic, due to the greater compactness of the reduced molecule or, alternatively, to a lower rate of conformational fluctuation caused by solvation, electrostatic, and structural factors. The biophysical consequences of the large difference in the stabilities of the closed crevice structures are discussed.     

Structure of a novel c7-type three-heme cytochrome domain from a multidomain cytochrome c polymer

The structure of a novel c(7)-type cytochrome domain that has two bishistidine coordinated hemes and one heme with histidine, methionine coordination (where the sixth ligand is a methionine residue) was determined at 1.7 A resolution. This domain is a representative of domains that form three polymers encoded by the Geobacter sulfurreducens genome. Two of these polymers consist of four and one protein of nine c(7)-type domains with a total of 12 and 27 hemes, respectively. Four individual domains (termed A, B, C, and D) from one such multiheme cytochrome c (ORF03300) were cloned and expressed in Escherichia coli. The domain C produced diffraction quality crystals from 2.4 M sodium malonate (pH 7). The structure was solved by MAD method and refined to an R-factor of 19.5% and R-free of 21.8%. Unlike the two c(7) molecules with known structures, one from G. sulfurreducens (PpcA) and one from Desulfuromonas acetoxidans where all three hemes are bishistidine coordinated, this domain contains a heme which is coordinated by a methionine and a histidine residue. As a result, the corresponding heme could have a higher potential than the other two hemes. The apparent midpoint reduction potential, E(app), of domain C is -105 mV, 50 mV higher than that of PpcA.