Flavodoxin-cytochrome c interactions: circular dichroism and nuclear magnetic resonance studies

Circular dichroism and 1H and 31P nuclear magnetic resonance spectroscopy have been used to investigate complex formation between cytochrome c and the flavodoxins from Azotobacter vinelandii and Clostridium pasteurianum. Such complexes are known to be involved in the mechanism of electron transfer between these two redox proteins. A large increase in ellipticity in the Soret band of the cytochrome heme was observed upon formation of the Clostridium flavodoxin complex, whereas much smaller changes were found for the complexes with either Azotobacter flavodoxin or an 8 alpha-imidazolyl-FMN-substituted Clostridium flavodoxin analogue. Similarly, the magnitudes of the perturbations of the contact-shifted heme proton resonances obtained upon complexation of cytochrome c by Azotobacter flavodoxin were much smaller than those previously shown for Clostridium flavodoxin [Hazzard, J. T., & Tollin, G. (1985) Biochem. Biophys. Res. Commun. 130, 1281-1286]. 31P nuclear magnetic resonance measurements were also consistent with differences in the interactions between the components in the complexes of the two flavodoxins with cytochrome c. It is suggested that these spectral changes are due to a loosening or opening of the heme crevice upon Clostridium flavodoxin binding, which allows closer contact between the heme and flavin prosthetic groups and results in a faster rate of electron transfer. The implications of these observations for biological oxidation-reduction processes are considered.     

A proton NMR study of the non-covalent complex of horse cytochrome c and yeast cytochrome-c peroxidase and its comparison with other interacting protein complexes

Cytochrome-c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) forms a noncovalent 1:1 complex with horse cytochrome c in low ionic strength solution that is detectable by proton NMR spectroscopy. When the entire proton hyperfine-shifted spectrum is considered only five hyperfine resonances exhibit unambiguously detectable shifts: the heme 8-CH3 and 3-CH3 resonances, single proton resonances near 19 ppm and -4 ppm and the methionine-80 methyl group. These shifts are very similar to those observed for the covalently crosslinked complex of cytochrome-c peroxidase and horse cytochrome c, but different from those reported for cytochrome c complexes with flavodoxin and cytochrome b5. By comparison with the shifts reported for lysine-13-modified cytochrome c we conclude that the results reported here support the Poulos-Kraut proposed structure for the molecular redox complex between cytochrome-c peroxidase and cytochrome c. These results indicate that the principal site of interaction with cytochrome-c peroxidase is the exposed heme edge of horse cytochrome c, in proximity to lysine-13 and the heme pyrrole II. The noncovalent cytochrome-c peroxidase-cytochrome c complex exists in the rapid-exchange time limit even at 500 mHz proton frequency. Our data provide an improved estimate of the minimum off-rate for exchanging cytochrome c as 1133 (+/- 120) s-1 at 23 degrees C.     

Transient kinetics of electron transfer reactions of flavodoxin: ionic strength dependence of semiquinone oxidation by cytochrome c, ferricyanide, and ferric ethylenediaminetetraacetic acid and computer modeling of reaction complexes

Electron transfer reactions between Clostridum pasteurianum flavodoxin semiquinone and various oxidants [horse heart cytochrome c, ferricyanide, and ferric ethylenediaminetetraacetic [horse heart cytochrome c, ferricyanide, and ferric ethylenediaminetetraacetic acid (EDTA)] have been studied as a function of ionic strength by using stopped-flow spectrophotometry. The cytochrome c reaction is complicated by the existence of two cytochrome species which react at different rates and whose relative concentrations are ionic strength dependent. Only the faster of these two reactions is considered here. At low ionic strength, complex formation between cytochrome c and flavodoxin is indicated by a leveling off of the pseudo-first-order rate constant at high cytochrome c concentration. This is not observed for either ferricyanide or ferric EDTA. For cytochrome c, the rate and association constants for complex formation were found to increase with decreasing ionic strength, consistent with negative charges on flavodoxin interacting with the positively charged cytochrome electron transfer site. Both ferricyanide and ferric EDTA are negatively charged oxidants, and the rate data respond to ionic strength changes as would be predicted for reactants of the same charge sign. These results demonstrate that electrostatic interactions involving negatively charged groups are important in orienting flavodoxin with respect to oxidants during electron transfer. We have also carried out computer modeling studies of putative complexes of flavodoxin with cytochrome c and ferricyanide, which relate their structural properties to both the observed kinetic behavior and some more general features of physiological electron transfer processes. The results of this study are consistent with the ionic strength behavior described above.     

A hypothetical model of the flavodoxin-tetraheme cytochrome c3 complex of sulfate-reducing bacteria

A hypothetical model of the flavodoxin-tetraheme cytochrome c3 electron-transfer complex from the sulfate-reducing bacterium Desulfovibrio vulgaris has been constructed by using interactive computer graphics based on electrostatic potential field calculations and previous NMR experiments. Features of the proposed complex are (1) van der Waals contact between the flavin mononucleotide prosthetic group of flavodoxin and one heme of the cytochrome, (2) unique complementarity of electrostatic fields between the region surrounding this heme and the region surrounding the exposed portion of the flavin mononucleotide group of flavodoxin, and (3) no steric interferences between the two polypeptide chains in the complex. This complex is consistent with all structural and spectroscopic data available.     

Kinetics of electron transfer between cytochromes c' and the semiquinones of free flavin and clostridial flavodoxin

Rate constants have been measured for the reactions of a series of high-spin cytochromes c' and their low-spin homologues (cytochromes c-554 and c-556) with the semiquinones of free flavins and flavodoxin. These cytochromes are approximately 3 times more reactive with lumiflavin and riboflavin semiquinones than are the c-type cytochromes that are homologous to mitochondrial cytochrome c. We attribute this to the greater solvent exposure of the heme in the c'-type cytochromes. In marked contrast, the cytochromes c' are 3 orders of magnitude less reactive with flavodoxin semiquinone than are the c-type cytochromes. We interpret this result to be a consequence of the location of the exposed heme in cytochrome c' at the bottom of a deep groove in the surface of the protein, which is approximately 10-15 A deep and equally as wide. While free flavins are small enough to enter the groove, the flavin mononucleotide (FMN) prosthetic group of flavodoxin is apparently prevented by steric constraints from approaching the heme more closely than approximately 10 A without dynamic structural rearrangements. Most cytochromes c' are dimeric, but a few are monomeric. The three-dimensional structure of the Rhodospirillum molischianum cytochrome c' dimer suggests that the heme should be more exposed in the monomer than in the dimer, but no relationship is observed between intrinsic reactivity toward free flavin semiquinones and the aggregation state of the protein. Likewise, there is no evidence that the spin state or ligand field of the iron has any effect on intrinsic reactivity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transient kinetics of redox reactions of flavodoxin: effects of chemical modification of the flavin mononucleotide prosthetic group on the dynamics of intermediate complex formation and electron transfer

The effects of structural modifications of the flavin mononucleotide (FMN) prosthetic group of Clostridium pasteurianum flavodoxin on the kinetics of electron transfer to the oxidized form (from 5-deazariboflavin semiquinone produced by laser flash photolysis) and from the semiquinone form (to horse heart cytochrome c by using stopped-flow spectrophotometry) have been investigated. The analogues used were 7,8-dichloro-FMN, 8-chloro-FMN, 7-chloro-FMN, and 5,6,7,8-tetrahydro-FMN. The ionic strength dependence of cytochrome c reduction was not affected by chlorine substitution, although the specific rate constants for complex formation and decay were appreciably smaller. On the other hand, all of the chlorine analogues had the same rate constant for deazariboflavin semiquinone oxidation. The rate constants for tetrahydro-FMN flavodoxin semiquinone reduction of cytochrome c were considerably smaller than those for the native protein. The implications of these results for the electron-transfer mechanism of flavodoxin are discussed.     

Complex formation between flavodoxin and cytochrome c. Cross-linking studies

Complex formation between Azotobacter vinelandii flavodoxin and horse cytochrome c has been demonstrated through cross-linking studies with dimethyl suberimidate, dimethyl adipimidate, 1-ethyl-3-(3-di-methylaminopropyl)carbodiimide, and dimethyl-3,3'-dithiobispropionimidate. Essentially quantitative cross-linking of cytochrome c and flavodoxin was observed at low ionic strengths with the carbodiimide cross-linking reagent. An association constant of 4 X 10(4) M-1 was obtained between cytochrome c and flavodoxin at 88 mM ionic strength from analysis of the cross-linking studies. This value is similar to the association constant determined kinetically during the electron transfer reaction between cytochrome c and flavodoxin (Simondsen, R.P., Weber, P.C., Salemme, F.R., and Tollin, G. (1982) Biochemistry 21, 6366-6375), and suggests that the cross-linked complex may be similar to the precursor complex identified kinetically. A structural model for the flavodoxin-cytochrome c complex proposed by these workers is shown to be compatible with the present cross-linking results.     

Electronic and vibrational spectroscopy of the cytochrome c:cytochrome c oxidase complexes from bovine and Paracoccus denitrificans.

The 1:1 complex between horse heart cytochrome c and bovine cytochrome c oxidase, and between yeast cytochrome c and Paracoccus denitrificans cytochrome c oxidase have been studied by a combination of second derivative absorption, circular dichroism (CD), and resonance Raman spectroscopy. The second derivative absorption and CD spectra reveal changes in the electronic transitions of cytochrome a upon complex formation. These results could reflect changes in ground state heme structure or changes in the protein environment surrounding the chromophore that affect either the ground or excited electronic states. The resonance Raman spectrum, on the other hand, reflects the heme structure in the ground electronic state only and shows no significant difference between cytochrome a vibrations in the complex or free enzyme. The only major difference between the Raman spectra of the free enzyme and complex is a broadening of the cytochrome a3 formyl band of the complex that is relieved upon complex dissociation at high ionic strength. These data suggest that the differences observed in the second derivative and CD spectra are the result of changes in the protein environment around cytochrome a that affect the electronic excited state. By analogy to other protein-chromophore systems, we suggest that the energy of the Soret pi* state of cytochrome a may be affected by (1) changes in the local dielectric, possibly brought about by movement of a charged amino acid side chain in proximity to the heme group, or (2) pi-pi interactions between the heme and aromatic amino acid residues.     

Kinetics of flavin semiquinone reduction of the components of the cytochrome c-cytochrome b5 complex

The kinetics of flavin semiquinone reduction of the components of the 1:1 complex formed by cytochrome c with either cytochrome b5 or a derivative of cytochrome b5 in which the heme propionates are esterified (DME-cytochrome b5) have been studied. The rate constant for the reduction of horse heart cytochrome c by the electrostatically neutral lumiflavin semiquinone (LfH) is unaffected by complexation with native cytochrome b5 at pH 7. However, complex formation with DME-cytochrome b5 (pH 7) decreases by 35% the rate constant for cytochrome c reduction by LfH. At pH 8, complex formation with native cytochrome b5 decreases the rate constant for cytochrome c reduction by LfH markedly, whereas the rate constant for cytochrome c reduction, either unbound or in the complex formed with DME-cytochrome b5, is increased 2-fold relative to pH 7. These results indicate that the accessibility of the cytochrome c heme is not the same in the complexes formed with the two cytochrome b5 derivatives and that the docking geometry of the complex formed by the two native cytochromes is pH dependent. Binding of horse heart and tuna cytochromes c to native and DME-cytochromes b5 decreases the rate constants for reduction of cytochrome c by the negatively charged flavin mononucleotide semiquinone (FMNH) by approximately 30% and approximately 40%, respectively. This finding is attributed to substantial neutralization of the positive electrostatic potential surface of cytochrome c that occurs when it binds to either form of cytochrome b5.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural changes in cytochrome c oxidase induced by cytochrome c binding. A resonance raman study

Electrostatically stabilized complexes of fully oxidized cytochrome c oxidase from Paracoccus denitrificans and horse heart cytochrome c were studied by resonance Raman spectroscopy. The experiments were carried out with the wild-type oxidase and a variant in which a negatively charged amino acid in the binding domain (D257) is replaced by an asparagine. It is shown that cytochrome c induces structural changes at heme a and heme a(3) which are reminiscent to those found in mammalian cytochrome c oxidase-cytochrome c complex. The spectral changes are attributed to subtle changes in the heme-protein interactions implying that there is a structural communication from the binding domain even to the remote catalytic center. Only for the heme a modes minor spectral differences were found in the response of the wild-type and the D257N variant oxidase upon cytochrome c binding indicating that electrostatic interactions of aspartate 257 are not crucial for the perturbation of the catalytic site structure in the complex. On the other hand, in none of the complexes, structural changes were detected in the bound cytochrome c. These findings are in contrast to previous results obtained with beef heart cytochrome c oxidase which triggers the formation of a new conformational state of cytochrome c assumed to be involved in the biological electron transfer process.     

A complex of cardiac cytochrome c1 and cytochrome c.

The interactions of cytochrome c1 and cytochrome c from bovine cardiac mitochondria were investigated. Cytochrome c1 and cytochrome c formed a 1:1 molecular complex in aqueous solutions of low ionic strength. The complex was stable to Sephadex G-75 chromatography. The formation and stability of the complex were independent of the oxidation state of the cytochrome components as far as those reactions studied were concerned. The complex was dissociated in solutions of ionic strength higher than 0.07 or pH exceeding 10 and only partially dissociated in 8 M urea. No complexation occurred when cytochrome c was acetylated on 64% of its lysine residues or photooxidized on its 2 methionine residues. Complexes with molecular ratios of less than 1:1 (i.e. more cytochrome c) were obtained when polymerized cytochrome c, or cytochrome c with all lysine residues guanidinated, or a "1-65 heme peptide" from cyanogen bromide cleavage of cytochrome c was used. These results were interpreted to imply that the complex was predominantly maintained by ionic interactions probably involving some of the lysine residues of cytochrome c but with major stabilization dependent on the native conformations of both cytochromes. The reduced complex was autooxidizable with biphasic kinetics with first order rate constants of 6 X 10(-5) and 5 X U0(-5) s-1 but did not react with carbon monoxide. The complex reacted with cyanide and was reduced by ascorbate at about 32% and 40% respectively, of the rates of reaction with cytochrome c alone. The complex was less photoreducible than cytochrome c1 alone. The complex exhibited remarkably different circular dichroic behavior from that of the summation of cytochrome c1 plus cytochrome c. We concluded that when cytochromes c1 and c interacted they underwent dramatic conformational changes resulting in weakening of their heme crevices. All results available would indicate that in the complex cytochrome c1 was bound at the entrance to the heme crevice of cytochrome c on the methionine-80 side of the heme crevice.     

Modeling electron transfer thermodynamics in protein complexes: interaction between two cytochromes c(3)

Redox protein complexes between type I and type II tetraheme cytochromes c(3) from Desulfovibrio vulgaris Hildenborough are here analyzed using theoretical methodologies. Various complexes were generated using rigid-body docking techniques, and the two lowest energy complexes (1 and 2) were relaxed using molecular dynamics simulations with explicit solvent and subjected to further characterization. Complex 1 corresponds to an interaction between hemes I from both cytochromes c(3). Complex 2 corresponds to an interaction between the heme IV from type I and the heme I from type II cytochrome c(3). Binding free energy calculations using molecular mechanics, Poisson-Boltzmann, and surface accessibility methods show that complex 2 is more stable than complex 1. Thermodynamic calculations on complex 2 show that complex formation induces changes in the reduction potential of both cytochromes c(3), but the changes are larger in the type I cytochrome c(3) (the largest one occurring on heme IV, of approximately 80 mV). These changes are sufficient to invert the global titration curves of both cytochromes, generating directionally in electron transfer from type I to type II cytochrome c(3), a phenomenon of obvious thermodynamic origin and consequences, but also with kinetic implications. The existence of processes like this occurring at complex formation may constitute a natural design of efficient redox chains.     

Biogenesis of cytochrome c1. Role of cytochrome c1 heme lyase and of the two proteolytic processing steps during import into mitochondria

The biogenesis of cytochrome c1 involves a number of steps including: synthesis as a precursor with a bipartite signal sequence, transfer across the outer and inner mitochondrial membranes, removal of the first part of the presequence in the matrix, reexport to the outer surface of the inner membrane, covalent addition of heme, and removal of the remainder of the presequence. In this report we have focused on the steps of heme addition, catalyzed by cytochrome c1 heme lyase, and of proteolytic processing during cytochrome c1 import into mitochondria. Following translocation from the matrix side to the intermembrane-space side of the inner membrane, apocytochrome c1 forms a complex with cytochrome c1 heme lyase, and then holocytochrome c1 formation occurs. Holocytochrome c1 formation can also be observed in detergent-solubilized preparations of mitochondria, but only after apocytochrome c1 has first interacted with cytochrome c1 heme lyase to produce this complex. Heme linkage takes place on the intermembrane-space side of the inner mitochondrial membrane and is dependent on NADH plus a cytosolic cofactor that can be replaced by flavin nucleotides. NADH and FMN appear to be necessary for reduction of heme prior to its linkage to apocytochrome c1. The second proteolytic processing of cytochrome c1 does not take place unless the covalent linkage of heme to apocytochrome c1 precedes it. On the other hand, the cytochrome c1 heme lyase reaction itself does not require that processing of the cytochrome c1 precursor to intermediate size cytochrome c1 takes place first. In conclusion, cytochrome c1 heme lyase catalyzes an essential step in the import pathway of cytochrome c1, but it is not involved in the transmembrane movement of the precursor polypeptide. This is in contrast to the case for cytochrome c in which heme addition is coupled to its transport directly across the outer membrane into the intermembrane space.     

Small substrates and cytochrome c are oxidized at different sites of cytochrome c peroxidase.

Modeling studies suggest that electrons are transferred from cytochrome c to cytochrome c peroxidase (CcP) with cytochrome c predominantly bound at a site facing the gamma-meso edge of the CcP prosthetic heme group (Poulos, T.L., and Kraut, J. (1980) J. Biol. Chem. 255, 10322-10330). As shown here, guaiacol and ferrocyanide are oxidized at a different site of CcP. Thus, the oxidations of cytochrome c and guaiacol are differentially inactivated by phenylhydrazine and sodium azide. The loss of guaiacol oxidation activity correlates with covalent binding of 1 equivalent of [14C]phenylhydrazine to the protein, whereas the slower loss of cytochrome c activity correlates with the appearance of a 428-nm absorbance maximum attributed to the formation of a sigma-phenyl-iron heme complex. The delta-meso-phenyl and 8-hydroxymethyl derivatives of heme are formed as minor products. Catalytic oxidation of azide to the azidyl radical results in inactivation of CcP and formation of delta-meso-azidoheme. Reconstitution of apo-CcP with delta-meso-azido-, -ethyl-, and -(2-phenylethyl)heme yields holoproteins that give compound I species with H2O2 and exhibit 80, 59, and 31%, respectively, of the control kcat value for cytochrome c oxidation but little or no guaiacol or ferrocyanide oxidizing activity. Conversely, CcP reconstituted with gamma-meso-ethylheme is fully active in the oxidation of guaiacol and ferrocyanide but only retains 27% of the cytochrome c oxidizing activity. These results indicate that guaiacol and ferrocyanide are primarily oxidized near the delta-meso-heme edge rather than, like cytochrome c, at a surface site facing the gamma-meso edge.     

Transient protein interactions studied by NMR spectroscopy: the case of cytochrome C and adrenodoxin

The interaction between yeast iso-1-cytochrome c (C102T) and two forms of bovine adrenodoxin, the wild type and a truncated form comprising residues 4-108, has been investigated using a combination of one- and two-dimensional heteronuclear NMR spectroscopy. Chemical shift perturbations and line broadening of amide resonances in the [(15)N,(1)H]HSQC spectrum for both (15)N-labeled cytochrome c and adrenodoxin in the presence of the unlabeled partner protein indicate the formation of a transient complex, with a K(a) of (4 +/- 1) x 10(4) M(-)(1) and a lifetime of <3 ms. The perturbed residues map over a large surface area for both proteins. For cytochrome c, the dominating effects are located around the exposed heme edge but with other areas also affected upon formation of the complex. In the case of adrenodoxin, effects are seen in both the recognition and core domains, with the largest perturbations in the recognition domain. These results indicate that the complex has a dynamic nature, with delocalized binding of cytochrome c on adrenodoxin. A comparison with other transient complexes of redox proteins places this complex between well-defined complexes such as the cytochrome c-cytochrome c peroxidase complex and entirely dynamic complexes such as the cytochrome b(5)-myoglobin complex.     

Chromatium flavocytochrome c: kinetics of reduction of the heme subunit, and the flavocytochrome c-mitochondrial cytochrome c complex

The kinetics of reduction of Chromatium vinosum flavocytochrome c heme subunit by exogenous flavin neutral semiquinones generated by laser flash photolysis have been investigated. Unlike the holoprotein, the isolated heme subunit was appreciably reactive with lumiflavin neutral semiquinone. The measured rate constant for the reaction (2.7 X 10(7) M-1 S-1) was comparable to those of c-type cytochromes having similar redox potentials. The ionic strength dependence of the reaction with FMN neutral radical indicated that the heme subunit had a small negative charge at the site of reduction. Taken together, these results suggest that the active site of the heme subunit is buried on complexation with the flavin subunit in the holoprotein. Horse cytochrome c formed a strong complex with Chromatium, but not Chlorobium, flavocytochrome c. Possible physiological electron acceptors such as HiPIP, cytochrome c', and cytochrome c-555 apparently did not bind to the flavocytochromes c. The rate constant for reduction by lumiflavin radical of horse cytochrome c complexed to flavocytochrome c was about twofold smaller than for reduction of horse cytochrome c alone. Flavocytochrome c was itself unreactive with exogenous flavin semiquinones. The ionic strength dependence of the reduction of the complex by FMN radical was also smaller than for horse cytochrome c in the absence of flavocytochrome c. Sulfite, which forms an adduct with the protein-bound FAD (FAD is bound in an 8-alpha-S-cysteinyl linkage), did not affect the reduction of horse cytochrome c in its complex with flavocytochrome c. We conclude that horse cytochrome c is reduced directly by exogenous flavins in its complex with flavocytochrome c, although the kinetics are slightly modified. These results are not unlike observations made with complexes of mitochondrial cytochrome c with cytochrome oxidase or cytochrome b5.     

Unusual susceptibility of heme proteins to damage by glucose during non-enzymatic glycation

Glucose modifies the amino groups of proteins by a process of non-enzymatic glycation, leading to potentially deleterious effects on structure and function that have been implicated in the pathogenesis of diabetic complications. These changes are extremely complex and occur very slowly. We demonstrate here that hemoglobin and myoglobin are extremely susceptible to damage by glucose in vitro through a process that leads to complete destruction of the essential heme group. This process appears in addition to the expected formation of so-called advanced glycation end products (AGEs) on lysine and other side-chains. AGE formation is enhanced by the iron released. In contrast, the heme group is not destroyed during glycation of cytochrome c, where the sixth coordination position of the heme iron is not accessible to solvent ligands. Glycation leads to reduction of ferricytochrome c in this case. Since hydrogen peroxide is known to destroy heme, and the destruction observed during glycation of hemoglobin and myoglobin is sensitive to catalase, we propose that the degradation process is initiated by hydrogen peroxide formation. Damage may then occur through reaction with superoxide generated (a reductant of ferricytochrome c), or hydroxyl radicals, or with both.     

Redox interaction of cytochrome c3 with [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki F

Cytochrome c3 isolated from a sulfate-reducing bacterium, Desulfovibrio vulgaris Miyazaki F, is a tetraheme protein. Its physiological partner, [NiFe] hydrogenase, catalyzes the reversible oxidoreduction of molecular hydrogen. To elucidate the mechanism of electron transfer between cytochrome c3 and [NiFe] hydrogenase, the transient complex formation by these proteins was investigated by means of NMR. All NH signals of uniformly 15N-labeled ferric cytochrome c3 except N-terminus, Pro, and Gly73 were assigned. 1H-15N HSQC spectra were recorded for 15N-labeled ferric and ferrous cytochrome c3, in the absence and presence of hydrogenase. Chemical shift perturbations were observed in the region around heme 4 in both oxidation states. Additionally, the region between hemes 1 and 3 in ferrous cytochrome c3 was affected in the presence of hydrogenase, suggesting that the mode of interaction is different in each redox state. Heme 3 is probably the electron gate for ferrous cytochrome c3. To investigate the transient complex of cytochrome c3 and hydrogenase in detail, modeling of the complex was performed for the oxidized proteins using a docking program, ZDOCK 2.3, and NMR data. Furthermore, the roles of lysine residues of cytochrome c3 in the interaction with hydrogenase were investigated by site-directed mutagenesis. When the lysine residues around heme 4 were replaced by an uncharged residue, methionine, one by one, the Km of the electron-transfer kinetics increased. The results showed that the positive charges of Lys60, Lys72, Lys95, and Lys101 around heme 4 are important for formation of the transient complex with [NiFe] hydrogenase in the initial stage of the cytochrome c3 reduction. This finding is consistent with the most possible structure of the transient complex obtained by modeling.     

Three-dimensional structure of the nonaheme cytochrome c from Desulfovibrio desulfuricans Essex in the Fe(III) state at 1.89 A resolution

A nine heme group containing cytochrome c isolated from the soluble and membrane fractions of Desulfovibrio desulfuricans Essex, termed nonaheme cytochrome c, was crystallized, and the structure was solved using the multiple wavelength anomalous dispersion (MAD) phasing method. Refinement was carried out to a resolution of 1.89 A, and anisotropic temperature factors were addressed to the iron and sulfur atoms in the model. The structure revealed two cytochrome c(3) like domains with the typical arrangement of four heme centers. Both domains flanked an extra heme buried under the protein surface. This heme is held in position by loop extensions in each of the two domains. Although both the N- and C-terminal tetraheme domains exhibit a fold and heme arrangement very similar to that of cytochrome c(3), they differ considerably in their loop extensions and electrostatic surface. Analysis of the structure provides evidence for a different function of both domains, namely, anchoring the protein in a transmembranous complex with the N-terminal domain and formation of an electron-transfer complex with hydrogenase by the C-terminal domain.