Substitution of the sixth axial ligand of Rhodobacter capsulatus cytochrome c1 heme yields novel cytochrome c1 variants with unusual properties.

The cytochrome (cyt) c1 heme of the ubihydroquinone:cytochrome c oxidoreductase (bc1 complex) is covalently attached to two cysteine residues of the cyt c1 polypeptide chain via two thioether bonds, and the fifth and sixth axial ligands of its iron atom are histidine (H) and methionine (M), respectively. The latter residue is M183 in Rhodobacter capsulatus cyt c1, and previous mutagenesis studies revealed its critical role for the physicochemical properties of cyt c1 [Gray, K. A., Davidson, E., and Daldal, F. (1992) Biochemistry 31, 11864-11873]. In the homologous chloroplast b6f complex, the sixth axial ligand is provided by the amino group of the amino terminal tyrosine residue. To further pursue our investigation on the role played by the sixth axial ligand in heme-protein interactions, novel cyt c1 variants with histidine-lysine (K) and histidine-histidine axial coordination were sought. Using a R. capsulatus genetic system, the cyt c1 mutants M183K and M183H were constructed by site-directed mutagenesis, and chromatophore membranes as well as purified bc1 complexes obtained from these mutants were characterized in detail. The studies revealed that these mutants incorporated the heme group into the mature cyt c1 polypeptides, but yielded nonfunctional bc1 complexes with unusual spectroscopic and thermodynamic properties, including shifted optical absorption maxima (lambdamax) and decreased redox midpoint potential values (Em7). The availability and future detailed studies of these stable cyt c1 mutants should contribute to our understanding of how different factors influence the physicochemical and folding properties of membrane-bound c-type cytochromes in general.     

Cytochromes c555 from the hyperthermophilic bacterium Aquifex aeolicus. 2. Heterologous production of soluble cytochrome c555s and investigation of the role of methionine residues.

The cycB2 gene encoding the soluble cytochrome c555s from Aquifex aeolicus, an hyperthermophilic organism, has been cloned and expressed using Escherichia coli as the host organism. The cytochrome was successfully produced in the periplasm of an E. coli strain coexpressing the ccmABCDEFGH genes involved in the cytochrome c maturation process. Comparison of native and recombinant cytochrome c555s shows that both proteins are indistinguishable in terms of spectroscopic and physicochemical properties. Since two different methionine residues are present in the sequence stretch usually providing the sixth ligand to the heme iron, site-directed mutagenesis has been performed in order to identify the methionine serving as the axial ligand. Two single mutations were introduced, leading to the replacement of each methionine by a histidine residue. Characterization of both mutants, M78H and M84H cytochromes c555s, using biochemical and biophysical techniques has been carried out. The M84H mutant exhibits spectral features identical to those of native cytochrome. Its redox midpoint potential is decreased by 40 mV. By contrast, substitution of methionine 78 by a histidine residue strongly alters the structural and physicochemical properties of the molecule which exhibits characteristics of His/His iron coordination type rather than His/Met. These results allow us to identify methionine 78 as the sixth ligand of cytochrome c555s heme iron. Preliminary results on the thermostability of the native and mutant cytochromes c555 are also reported.     

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.     

Role of the aromatic ring of Tyr43 in tetraheme cytochrome c(3) from Desulfovibrio vulgaris Miyazaki F

Tyrosine 43 is positioned parallel to the fifth heme axial ligand, His34, of heme 1 in the tetraheme cytochrome c(3). The replacement of tyrosine with leucine increased the redox potential of heme 1 by 44 and 35 mV at the first and last reduction steps, respectively; its effects on the other hemes are small. In contrast, the Y43F mutation hardly changed the potentials. It shows that the aromatic ring at this position contributes to lowering the redox potential of heme 1 locally, although this cannot be the major contribution to the extremely low redox potentials of cytochrome c(3). Furthermore, temperature-dependent line-width broadening in partially reduced samples established that the aromatic ring at position 43 participates in the control of the kinetics of intramolecular electron transfer. The rate of reduction of Y43L cytochrome c(3) by 5-deazariboflavin semiquinone under partially reduced conditions was significantly different from that of the wild type in the last stage of the reduction, supporting the involvement of Tyr43 in regulation of reduction kinetics. The mutation of Y43L, however, did not induce a significant change in the crystal structure.     

Some properties of mammalian cardiac cytochrome c1.

Investigations into the nature of the axial heme ligands, the strength of the heme crevice, the reactivity with cyanide, and the ascorbate reducibility of cytochrome c1 were performed to explore structure-function relationships of cytochrome c1. The existence of an absorbance band at 690 nm, which was quenched by raising the pH with a pK of 9.2 corresponding to a low spin-low transition, suggested that a methionine residue probably functioned as one of the axial heme iron ligands in this cytochrome. Spectral titrations of cytochrome c1 in the low pH range showed a markedly elevated pK for the low spin-high spin transition relative to cytochrome c. Denaturation studies with urea, the absence of any reaction with cyanide, and the evidence from other lines would appear to indicate that the heme group of cytochrome c1 was reduced by ascorbate at approximately 5% of the rate of reduction of cytochrome c but this rate dramatically increased with increasing pH concomitant with the disappearance of the 690 nm absorbance band. Circular dichroic spectra substantiated that elevated pH produced conformational changes localized to the heme crevice and probably also the regions containing aromatic residues. The enhanced rate of ascorbate reduction was perhaps a consequence of the increased accessibility of the heme iron to ascorbate. Major unfolding of the protein in 8 M urea, however, completely abolished the ascorbate reducibility of cytochrome c1. The buried nature of the heme group of cytochrome c1 would probably preclude transfer of an electron from cytochrome c1 to cytochrome c through a direct Fe-Fe or a heme-heme interaction. This poses an important question concerning the mechanism of this electron transfer between these two cytochromes not only in mitochondria but also in solution.     

Crystal structure of Nitrosomonas europaea cytochrome c peroxidase and the structural basis for ligand switching in bacterial di-heme peroxidases.

The crystal structure of the fully oxidized di-heme peroxidase from Nitrosomonas europaea has been solved to a resolution of 1.80 A and compared to the closely related enzyme from Pseudomonas aeruginosa. Both enzymes catalyze the peroxide-dependent oxidation of a protein electron donor such as cytochrome c. Electrons enter the enzyme through the high-potential heme followed by electron transfer to the low-potential heme, the site of peroxide activation. Both enzymes form homodimers, each of which folds into two distinct heme domains. Each heme is held in place by thioether bonds between the heme vinyl groups and Cys residues. The high-potential heme in both enzymes has Met and His as axial heme ligands. In the Pseudomonas enzyme, the low-potential heme has two His residues as axial heme ligands [Fulop et al. (1995) Structure 3, 1225-1233]. Since the site of reaction with peroxide is the low-potential heme, then one His ligand must first dissociate. In sharp contrast, the low-potential heme in the Nitrosomonas enzyme already is in the "activated" state with only one His ligand and an open distal axial ligation position available for reaction with peroxide. A comparison between the two enzymes illustrates the range of conformational changes required to activate the Pseudomonas enzyme. This change involves a large motion of a loop containing the dissociable His ligand from the heme pocket to the molecular surface where it forms part of the dimer interface. Since the Nitrosomonas enzyme is in the active state, the structure provides some insights on residues involved in peroxide activation. Most importantly, a Glu residue situated near the peroxide binding site could possibly serve as an acid-base catalytic group required for cleavage of the peroxide O--O bond.     

1H NMR studies of the effect of mutation at Valine45 on heme microenvironment of cytochrome b5

1D and 2D (1)H NMR were employed to probe the effects on the heme microenvironment of cytochrome b(5) caused by the mutation from Val45 to Tyr45, His45 and Glu45. Compared with wild type (WT) cytochrome b(5), in all mutants the heme ring are CCW rotated relative to the imidazole planes of axial ligands and the angles beta between two axial ligand imidazole planes are not changed, being in agreement with the temperature dependence of the shifts of the heme protons. The ratios of heme isomers (major to minor) are smaller than that in WT. The 4-vinyl group of the heme in V45Y assumes cis-orientation, being similar to that of WT, while in V45E and V45H, both cis and trans orientation are found. The relationships between the structure and biological function of the mutants are discussed in terms of the geometry of heme and axial ligands, the hydrophobicity of heme pocket and the electrostatic potential of the heme-exposed area.     

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.     

Resonance Raman study of multihemic c-type cytochromes from Desulfuromonas acetoxidans.

Two multihemic cytochromes c from the sulfur reducing bacteria Desulfuromonas acetoxidans have been studied by optical and resonance Raman spectroscopy: cytochrome c551.5, a trihemic cytochrome and cytochrome c Mr 50 000, a recently isolated high molecular mass cytochrome. The redox and Raman characteristics of cytochrome c551.5 are compared to those of the tetrahemic cytochromes c3 from Desulfovibrio. While the redox behavior, followed by spectroelectrochemistry, is similar to that of cytochrome c3, showing the same conformational change after reduction of the highest potential heme, the Raman data show a contribution from a His- form of the axial ligands and lead to the assignment of a band at 218 cm-1 to the Fe(III)-(His)2 stretching vibration. The Raman data on cytochrome c Mr 50 000 are in favor of an entirely low spin species with two different sets of axial ligands. A partially reduced state is easily accessible by ascorbate addition.     

Replacement of putative axial ligands of heme iron in yeast cytochrome c1 by site-directed mutagenesis

The His-44 and Met-164 residues of yeast cytochrome c1 are evolutionally conserved and regarded as heme axial ligands bonding to the fifth and sixth coordination sites of the heme iron, which is directly involved in the electron transfer mechanism. Oligonucleotide-directed mutagenesis was used to generate mutant forms of cytochrome c1 of yeast having amino acid replacements of the putative axial ligands of the heme iron. When a cytochrome c1-deficiency yeast strain was transformed with a gene encoding the Phe-44, Tyr-44, Leu-164, or Lys-164 protein, none of these transformants could grow on the non-fermentable carbon source. These results suggest that the His-44 and Met-164 residues have a critical role in the function of cytochrome c1 in vivo, most probably as axial ligands of the heme iron. Further analysis revealed that the mutant yeast cells with the Phe-44, Tyr-44, or Leu-164 protein lacked the characteristic difference spectroscopic signal of cytochrome c1. However, in the Lys-164 mutant cells, partial recovery of the cytochrome c1 signal was observed. Moreover, the Lys-164 protein retained a low but significant level of succinate-cytochrome c reductase activity in vitro. The possibility that the nitrogen of Lys-164 served as the sixth heme ligand is discussed in comparison with cytochrome f of a photosynthetic electron-transfer complex, in which lysine has been proposed to be the sixth ligand.     

Methionine sulfoxide cytochrome c.

Cytochrome c has been chemically modified by methylene blue mediated photooxidation. It is established that the methionine residues of the protein have been specifically converted to methionine sulfoxide residues. No oxidation of any other amino acid residues or the cysteine thioether bridges of the molecule occurs during the photooxidation reaction. The absorbance spectrum of methionine sulfoxide ferricytochrome c at neutrality is similar to that of the unmodified protein except for an increase in the extinction coefficient of the Soret absorbance band and for the complete loss of the ligand sensitive 695 nm absorbance band in the spectrum of the derivative. The protein remains in the low spin configuration which implies the retention of two strong field ligands. Spin state sensitive spectral titrations and model studies of heme peptides indicate that the sixth ligand is definitely not provided by a lysine residue but may be methionine-80 sulfoxide coordinated via its sulfur atom. Circular dichroism spectra indicate that the heme crevice of methionine sulfoxide ferri- and ferrocytochrome c is weakened relative to native cytochrome c. The redox potential of methionine sulfoxide cytochrome c is 184 mV which is markedly diminished from the 260 mV redox potential of native cytochrome c. The modified protein is equivalent to native cytochrome c as a substrate for cytochrome oxidase and is not autoxidizable at neutral pH but is virtually inactive with succinate-cytochrome c reductase. These results indicate that the major role of the methionine-80 in cytochrome c is to preserve a closed hydrophobic heme crevice which is essential for the maintainance of the necessary redox potential.     

1H NMR structural characterization of the cytochrome c modifications in a micellar environment

The interaction of cytochrome c with micelles of sodium dodecyl sulfate was studied by proton NMR spectroscopy. The protein/micelles ratio was found to be crucial in controlling the extent of the conformational changes in the heme crevice. Over a range of ratios between 1:30 and 1:60, the NMR spectra of the ferric form display no paramagnetic signals due to a moderately fast exchange between intermediate species on the NMR time scale. This is consistent with an interconversion of bis-histidine derivatives (His18-Fe-His26 and His18-Fe-His33). Further addition of micelles induces a high-spin species that is proposed to involve pentacoordinated iron. The resulting free binding site, also encountered in the ferrous form, is used to complex exogenous ligands such as cyanide or carbon monoxide. Attribution of the heme methyls was performed by means of exchange spectroscopy through ligand exchange or electron transfer. The heme methyl shift pattern of the micellar cyanocytochrome in the ferric low spin form is different from the pattern of both the native and the cyanide cytochrome c adduct, in the absence of micelles, reflecting a complete change of the heme electronic structure. Analysis of the electron self-exchange reaction between the two redox states of the micellar cyanocytochrome c yields a rate constant of 2.4 x 10(4) M(-1) s(-1) at 298 K, which is surprisingly close to the value observed in the native protein.     

Controlling the functionality of cytochrome c(1) redox potentials in the Rhodobacter capsulatus bc(1) complex through disulfide anchoring of a loop and a beta-branched amino acid near the heme-ligating methionine.

The cytochrome c(1) subunit of the ubihydroquinone:cytochrome c oxidoreductase (bc(1) complex) contains a single heme group covalently attached to the polypeptide via thioether bonds of two conserved cysteine residues. In the photosynthetic bacterium Rhodobacter (Rba.) capsulatus, cytochrome c(1) contains two additional cysteines, C144 and C167. Site-directed mutagenesis reveals a disulfide bond (rare in monoheme c-type cytochromes) anchoring C144 to C167, which is in the middle of an 18 amino acid loop that is present in some bacterial cytochromes c(1) but absent in higher organisms. Both single and double Cys to Ala substitutions drastically lower the +320 mV redox potential of the native form to below 0 mV, yielding nonfunctional cytochrome bc(1). In sharp contrast to the native protein, mutant cytochrome c(1) binds carbon monoxide (CO) in the reduced form, indicating an opening of the heme environment that is correlated with the drop in potential. In revertants, loss of the disulfide bond is remediated uniquely by insertion of a beta-branched amino acid two residues away from the heme-ligating methionine 183, identifying the pattern betaXM, naturally common in many other high-potential cytochromes c. Despite the unrepaired disulfide bond, the betaXM revertants are no longer vulnerable to CO binding and restore function by raising the redox potential to +227 mV, which is remarkably close to the value of the betaXM containing but loop-free mitochondrial cytochrome c(1). The disulfide anchored loop and betaXM motifs appear to be two independent but nonadditive strategies to control the integrity of the heme-binding pocket and raise cytochrome c midpoint potentials.     

Mutagenesis of methionine-183 drastically affects the physicochemical properties of cytochrome c1 of the bc1 complex of Rhodobacter capsulatus.

Site-directed mutagenesis was used to investigate which of the highly conserved methionine residues (M183 and M205) provides the sixth axial ligand to the heme Fe in the cyt c1 subunit of the bc1 complex from the bacterium Rhodobacter capsulatus. These residues were changed to leucine (cM183L) and valine (cM205V). Two additional mutants were constructed, 1 in which a stop codon was inserted at M205 (cM205*) and the second in which 127 amino acids were deleted between the signal sequence and the putative C-terminal transmembrane alpha-helix (c delta SfuI). Only cM205V grew photosynthetically, and membranes isolated from this strain catalyzed quinol-dependent reduction of cyt c in amounts similar to that in a wild-type strain. Even though cM183L could not grow photosynthetically, it contained all the appropriate polypeptides and cofactors of the bc1 complex, as shown by SDS-PAGE and optical difference spectroscopy of intact membrane particles. Neither of the two deletion mutants contained a stable complex. Flash absorption spectroscopy using chromatophores showed no cytochrome c rereduction after oxidation by the reaction center in cM183L. The bc1 complex from each strain was isolated and characterized. Oxidation reduction midpoint potential titrations revealed that cyt c1 from cM183L had a dramatically shifted Em value (delta Em = -390 mV) compared with wild type and cM205V. While the optical absorption spectrum of cyt c1 from cM183L suggested that the c-type heme was low-spin, nonetheless it was able to react with the exogenous ligand carbon monoxide. The overall data support that M183, and not M205, is the sixth ligand to the heme Fe of cyt c1 of the bc1 complex.     

Structure and reaction mechanisms of multifunctional mitochondrial cytochrome bc1 complex.

The cytochrome bc1 complex from bovine heart mitochondria is a multi-functional enzyme complex. In addition to electron and proton transfer activity, the complex also processes an activatable peptidase activity and a superoxide generating activity. The crystal structure of the complex exists as a closely interacting functional dimer. There are 13 transmembrane helices in each monomer, eight of which belong to cytochrome b, and five of which belong to cytochrome c1, Rieske iron-sulfur protein (ISP), subunits 7, 10 and 11, one each. The distances of 21 A between bL heme and bH heme and of 27 A between bL heme and the iron-sulfur cluster (FeS), accommodate well the observed fast electron transfers between the involved redox centers. However, the distance of 31 A between heme c1 and FeS, makes it difficult to explain the high electron transfer rate between them. 3D structural analyses of the bc1 complexes co-crystallized with the Qu site inhibitors suggest that the extramembrane domain of the ISP may undergo substantial movement during the catalytic cycle of the complex. This suggestion is further supported by the decreased in the cytochrome bc1 complex activity and the increased in activation energy for mutants with increased rigidity in the neck region of ISP.     

The axial ligands of heme in cytochromes: a near-infrared magnetic circular dichroism study of yeast cytochromes c, c1, and b and spinach cytochrome f

Room temperature near-infrared magnetic circular dichroism and low-temperature electron paramagnetic resonance measurements have been used to characterize the ligands of the heme iron in mitochondrial cytochromes c, c1, and b and in cytochrome f of the photosynthetic electron transport chain. The MCD data show that methionine is the sixth ligand of the heme of oxidized yeast cytochrome c1; the identify of this residue is inferred to be the single conserved methionine identified from a partial alignment of the available cytochrome c1 amino acid sequences. A different residue, which is most likely lysine, is the sixth heme ligand in oxidized spinach cytochrome f. The data for oxidized yeast cytochrome b are consistent with bis-histidine coordination of both hemes although the possibility that one of the hemes is ligated by histidine and lysine cannot be rigorously excluded. The neutral and alkaline forms of oxidized yeast cytochrome c have spectroscopic properties very similar to those of the horse heart proteins, and thus, by analogy, the sixth ligands are methionine and lysine, respectively.     

Cytochrome bc1 complexes of microorganisms.

The cytochrome bc1 complex is the most widely occurring electron transfer complex capable of energy transduction. Cytochrome bc1 complexes are found in the plasma membranes of phylogenetically diverse photosynthetic and respiring bacteria, and in the inner mitochondrial membrane of all eucaryotic cells. In all of these species the bc1 complex transfers electrons from a low-potential quinol to a higher-potential c-type cytochrome and links this electron transfer to proton translocation. Most bacteria also possess alternative pathways of quinol oxidation capable of circumventing the bc1 complex, but these pathways generally lack the energy-transducing, protontranslocating activity of the bc1 complex. All cytochrome bc1 complexes contain three electron transfer proteins which contain four redox prosthetic groups. These are cytochrome b, which contains two b heme groups that differ in their optical and thermodynamic properties; cytochrome c1, which contains a covalently bound c-type heme; and a 2Fe-2S iron-sulfur protein. The mechanism which links proton translocation to electron transfer through these proteins is the proton motive Q cycle, and this mechanism appears to be universal to all bc1 complexes. Experimentation is currently focused on understanding selected structure-function relationships prerequisite for these redox proteins to participate in the Q-cycle mechanism. The cytochrome bc1 complexes of mitochondria differ from those of bacteria, in that the former contain six to eight supernumerary polypeptides, in addition to the three redox proteins common to bacteria and mitochondria. These extra polypeptides are encoded in the nucleus and do not contain redox prosthetic groups. The functions of the supernumerary polypeptides of the mitochondrial bc1 complexes are generally not known and are being actively explored by genetically manipulating these proteins in Saccharomyces cerevisiae.     

Functional role of heme ligation in cytochrome c. Effects of replacement of methionine 80 with natural and non-natural residues by semisynthesis.

The nature of the axial ligation to heme iron has been suggested to be the major determinant of the oxidation-reduction potential of a particular cytochrome, but natural cytochromes that vary significantly in E'm invariably differ from one another in many ways. We proposed to clarify this issue by engineering many different ligation patterns within the same basic molecule, mitochondrial cytochrome c. Since many of the potentially informative substitutions require non-coded amino acids, semisynthesis was the approach we chose, and solid-phase peptide synthesis was used to make a set of nin 39-residue peptides that have been incorporated by autocatalytic fragment religation into the structure of horse cytochrome c. An additional two analogues modified at this position were made by chemical modification of the whole protein. As well as looking at the effect on reduction potential, we examined the effect of varying the ligand sphere on the efficiency of the autocatalytic fragment religation reaction, on the conformation of cytochrome c, on its spectroscopic properties, and in promoting electron transfer between heme c and other redox centers. Substitute residues were chosen to put sulfur, selenium, oxygen, and nitrogen, or even no ligating atom at all in the place of methionine sulfur. We found both subtle and dramatic alterations in spectral properties, which were informative about changes in internal structure and stability brought about by the modifications and which may be useful in identifying novel natural ligation patterns. An unexpected finding was that alanine 80 cytochrome c acquires a hemoglobin-like spectrum, and binds O2 most effectively. Reduction potential changes of greater than 300 mV with nitrogen, greater than 400 mV with oxygen, and greater than 300 mV with thiol sulfur ligation were observed, confirming that variation of the ligand sphere is indeed the most effective way in which the protein coat may modulate the potential of the redox center it encloses. Finally, we obtained more evidence that this axial ligand plays an active role in electron transfer and discovered that histidine could be even more effective in this role.     

Resonance Raman scattering from hemoproteins. Effects of ligands upon the Raman spectra of various C-type cytochromes.

Resonance Raman spectra were measured for various C-type cytochromes (mammalian cytochrome c, bacterial cytochrome c3, algal photosynthetic cytochrome f, and alkylated cytochrome c) and a B-type cytochrome (cytochrome b5) in their reduced and oxidized states. (1) For ferrous alkylated cytochrome c, a Raman line sensitive to the replacement of an axial ligand of the heme iron uas found around 1540 cm=1. This ligand-sensitive Raman line indicated the transition from acidic (1545 cm-1) to alkaline (1533 cm-1) forms with pK 7.9. The pH dependence of the Raman spectrum corresponded well to that of the optical absorption spectra. (2) For ferrous cytochrome f, the ligand-sensitive Raman line was found at the same frequency as cytochrome c (1545 cm-1). Accordingly two axial ligands are likely to be histidine and methionine as in cytochrome c. (3) For ferrous cytochrome c3, the frequency of the ligand-sensitive Raman line was between those of cytochrome c and cytochrome b5. Since two axial ligands of the heme iron in cytochrome c3 might be histidines. However, a combination of histidine and methionine as a possible set of two axial ligands was not completely excluded for one or two of the four hemes. (4) In ferrous cytochrome b5, two weak Raman lines appeared at 1302 and 1338 cm-1 instead of the strongest band at 1313 cm-1 of C-type ferrous cytochromes. This suggests the practical use of these bands for the identification of types of cytochromes. The difference in frequency and intensity between B- and C-types of hemes implies that the low effective symmetry of the heme in ferrous cytochrome c is due to vibrational coupling of ring modes with peripheral substituents rather than geometrical disortion of heme.     

Structural and functional characterization of the unusual triheme cytochrome bound to the reaction center of Rhodovulum sulfidophilum

The cytochrome bound to the photosynthetic reaction center of Rhodovulum sulfidophilum presents two unusual characteristics with respect to the well characterized tetraheme cytochromes. This cytochrome contains only three hemes because it lacks the peptide motif CXXCH, which binds the most distal fourth heme. In addition, we show that the sixth axial ligand of the third heme is a cysteine (Cys-148) instead of the usual methionine ligand. This ligand exchange results in a very low midpoint potential (-160 +/- 10 mV). The influence of the unusual cysteine ligand on the midpoint potential of this distal heme was further investigated by site-directed mutagenesis. The midpoint potential of this heme is upshifted to +310 mV when cysteine 148 is replaced by methionine, in agreement with the typical redox properties of a His/Met coordinated heme. Because of the large increase in the midpoint potential of the distal heme in the mutant, both the native and modified high potential hemes are photooxidized at a redox poise where only the former is photooxidizable in the wild type. The relative orientation of the three hemes, determined by EPR measurements, is shown different from tetraheme cytochromes. The evolutionary basis of the concomitant loss of the fourth heme and the down-conversion of the third heme is discussed in light of phylogenetic relationships of the Rhodovulum species triheme cytochromes to other reaction center-associated tetraheme cytochromes.