Nuclear magnetic resonance studies of hemoproteins. VIII. Proton NMR studies of the binding of various nitrogenous ligands to ferric cytochrome c.

The structure of the heme environment of horse heart ferric cytochrome c was examined in the presence of various nitrogenous bases at several temperatures with the aid of hyperfine shifted proton NMR spectra at 220 MHz. The resonance positions and line widths of the signals for the peripheral methyl groups of the heme exhibited distinctive features of its low-spin state characteristic of each external ligand. In the imidazole complex of ferric cytochrome c, remarkable line sharpening of the heme-linked proton signals was encountered on raising the temperature. This may be related to the apoprotein perturbation on the binding of external ligand to the heme iron. These spectral peculiarities were discussed in relation to the electronic structure of the heme, the basicity of the external ligand and the van der Waals contact interaction between heme side chains and apoprotein.     

Kinetic studies on cytochrome c oxidase by combined EPR and reflectance spectroscopy after rapid freezing

1. Techniques and experiments are described concerned with the millisecond kinetics of EPR-detectable changes brought about in cytochrome c oxidase by reduced cytochrome c and, after reduction with various agents, by reoxidation with O₂ or ferricyanide. Some experiments in the presence of ligands are also reported. Light absorption was monitored by low-temperature reflectance spectroscopy.2. In the rapid phase of reduction of cytochrome c oxidase by cytochrome c (< 50 ms) approx. 0.5 electron equivalent per hame a is transferred mainly to the low-spin heme component of cytochrome c oxidase and partly to the EPR-detectable copper. In a slow phase (> 1 s) the copper is reoxidized and high-spin ferric heme signals appear with a predominant rhombic component. Simultaneously the absorption band at 655 nm decreases and the Soret band at 444 nm appears between the split Soret band (442 and 447 nm) of reduced cytochrome a.3. On reoxidation of reduced enzyme by oxygen all EPR and optical features are restored within 6 ms. On reoxidation by O₂ in the presence of an excess of reduced cytochrome c, states can be observed where the low-spin heme and copper signals are largely absent but the absorption at 655 nm is maximal, indicating that the low-spin heme and copper components are at the substrate side and the component(s) represented in the 655 nm absorption at the O₂ side of the system. On reoxidation with ferricyanide the 655 nm absorption is not readily restored but a ferric high-spin heme, represented by a strong rhombic signal, accumulates.4. On reoxidation of partly reduced enzyme by oxygen, the rhombic high-spin signals disappear within 6 ms, whereas the axial signals disappear more slowly, indicating that these species are not in rapid equilibrium. Similar observations are made when partly reduced enzyme is mixed with CO.5. The results of this and the accompanying paper are discussed and on this basis an assignment of the major EPR signals and of the 655 nm absorption is proposed, which in essence is that published previously (Hartzell, C. R., Hansen, R. E. and Beinert, H. (1973) Proc. Natl. Acad. Sci. U.S. 70, 2477–2481). Both the low-spin (g = 3; 2.2; 1.5) and slowly appearing high-spin (g = 6; 2) signals are attributed to ferric cytochrome a, whereas the 655 nm absorption is thought to arise from ferric cytochrome a₃, when it is present in a state of interaction with EPR-undetectable copper. Alternative possibilities and possible inconsistencies with this proposal are discussed.     

Oxido-reductive titrations of cytochrome c oxidase followed by EPR spectroscopy

Experiments are described on oxido-reductive titrations of cytochrome c oxidase as followed by low-temperature EPR and reflectance spectroscopy. The reductants were cytochrome c or NADH and the oxidant ferricyanide. Experiments were conducted in the presence and absence of either cytochrome c or carbon monoxide, or both. An attempt is made to provide a complete quantitative balance of the changes observed in the major EPR signals. During reduction, the maximal quantity of heme represented in the high-spin ferric heme signals (g ～ 6; 2) is 25% of the total heme present, and during reoxidation 30%. With NADH reduction there is little difference between the pattern of disappearance of the low-spin ferric heme signals in the absence or presence of cytochrome c. The copper and high-spin heme signals, however, disappear at higher titrant concentrations in the presence of cytochrome c than in its absence. In these titrations, as well as in those with ferrocytochrome c, the quantitative balance indicates that, in addition to EPR-detectable components, EPR-undetectable components are also reduced, increasingly so at higher titrant concentrations. The quantity of EPR-undetectable components reduced appears to be inversely related to pH. A similar inverse relationship exists between pH and appearance of high-spin signals during the titration. At pH 9.3 the quantity of heme represented in the high-spin signals is < 5%, whereas it approximately doubles from pH 7.4 to pH 6.1. In the presence of CO less of the low-spin heme and copper signals disappears for the same quantity of titrant consumed, again implying reduction of EPR undetectable components. At least one of these components is represented in a broad absorption band centered at 655 nm. The stoichiometry observed on reoxidation, particularly in the presence of CO, is not compatible with the notion that the copper signal represents 100% of the active copper of the enzyme as a pair of interacting copper atoms.     

Proton magnetic relaxation and anion effect in solutions of acid ferricytochrome c.

Measurements of the longitudinal relaxation rates of water protons in aqueous solutions of ferricytochrome c and their temperature dependence, were used for the elucidation of the heme iron ligands at acid pH. The relaxation rates increased with a decrease in pH and pK values of 2.5 and 4.48 were evaluated for the aqueous and 6 m urea solutions, respectively. The results at acid pH are compatible with a structure in which two water molecules exchange rapidly between the coordination sphere of high spin heme iron and the bulk. They suggest that concomitantly with the low-high spin transition the histidine-18 and methionine-80 iron bonds break simultaneously. Addition of various anions, including methanesulfonate at pH 1.95 caused a 85% decrease in the net longitudinal relaxation rate. However, neither the chemical shift nor the width of the methyl proton nmr line of methanesulfonate in solution of acid ferricytochrome c were affected indicating that the effect of anions is not due to a direct binding to the heme iron. The relaxation mechanism of the water molecules in the first coordination sphere of the ferric ion in acid cytochrome c is discussed. It appears that the longitudial relaxation rate is modulated by the electronic correlation time of the ferric ion which was calculated to be τ_s = 6 × 10^?11 sec at 60 MHz.     

Structural and kinetic studies of imidazole binding to two members of the cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript>6</Subscript> family reveal an important role for a conserved heme pocket residue

The amino acid at position 51 in the cytochrome c ₆ family is responsible for modulating over 100 mV of heme midpoint redox potential. As part of the present work, the X-ray structure of the imidazole adduct of the photosynthetic cytochrome c ₆ Q51V variant from Phormidium laminosum has been determined. The structure reveals the axial Met ligand is dissociated from the heme iron but remains inside the heme pocket and the Ω-loop housing the Met ligand is stabilized through polar interactions with the imidazole and heme propionate-6. The latter is possible owing to a 180° rotation of both heme propionates upon imidazole binding. From equilibrium and kinetic studies, a Val residue at position 51 increases the stability of the Fe–S(Met) interaction and also affects the dynamics associated with imidazole binding. In this respect, the k _obs for imidazole binding to Arabidopsis thaliana cytochrome c _6A, which has a Val at the position equivalent to position 51 in photosynthetic cytochrome c ₆, was found to be independent of imidazole concentration, indicating that the binding process is limited by the Met dissociation rate constant (about 1 s⁻¹). For the cytochrome c ₆ Q51V variant, imidazole binding was suppressed in comparison with the wild-type protein and the V52Q variant of cytochrome c _6A was found to bind imidazole readily. We conclude that the residue type at position 51/52 in the cytochrome c ₆ family is additionally responsible for tuning the stability of the heme iron–Met bond and the dynamic properties of the ferric protein fold associated with endogenous ligand binding.     

EPR studies on cytochrome components in phosphorylating particles ofAzotobacter vinelandii

Oxidized particles ofA. vinelandii show high-spin ferric signals with an axial and a rhombically distorted component with g-values at 5.94 and 6.24, 5.51, respectively. The signals behave similarly on variation of temperature and/or power and are, assigned to cytochromed. The addition of ligands such as cyanide and carbon monoxide to oxidized particles mainly affects the rhombic component of the signal in the g=6 region. Prolonged, incubation of cyanide with oxidized particles results in the appearance of two new low-spin ferric heme signals at g=2.99 and at g=3.23 which are tentatively assigned to low-spin forms of cyanide-liganded cytochromed. With computer signal-averaging of the EPR spectrum of oxidized particles, the presence of resonances in the g=3–4 region could be demonstrated. These resonances are assigned to cytochromeb ₁ (g-values at 3.68, 3.43),c-type cytochromes (g-values at 3.43, 3.25) and cytochromea ₁, and possibly a low-spin form of ac-type cytochrome (g-value at 3.03). These EPR results represent, to our knowledge, the only such studies reported on the membrane-boundb ₁ andc-type cytochromes of a bacterial respiratory-linked phosphorylating electron-transport chain.     

Biochemical and biophysical studies on cytochrome c oxidase. XVIII. Potentiometric titrations of cytochrome c oxidase followed by circular dichroism

1. Potentiometric circular dichroism titrations of cytochrome c oxidase, carried out in the absence of cytochrome c, confirm the potentiometric equivalence of the two heme a groups of cytochrome c oxidase. In the presence of cytochrome c, two different midpoint potentials are found for the two heme a groups of cytochrome c oxidase.2. Circular dichroism difference spectra (reduced minus oxidized) of the two heme a components of cytochrome c oxidase have been obtained by means of this potentiometric titration. On reduction of the first heme a group a circular dichroism difference spectrum is obtained with peaks at 425, 442 and 602.5 nm; the second heme a group shows difference peaks at 434, 447 and 608 nm. Whereas both heme a groups contribute about equally to the absorbance difference spectrum, the second heme a group reduced contributes about twice as much to the circular dichroism difference spectrum as does the first heme a group.3. From these spectral and circular dichroism differences it is concluded that, on reduction of or ligand binding to cytochrome c oxidase, conformational changes occur which affect the symmetry of the environments of the heme a groups.     

Ionic Strength-Dependent Physicochemical Factors in Cytochrome c3 Regulating the Electron Transfer Rate

The effect of ionic strength on the macroscopic and microscopic redox potentials and the heme environment of cytochrome c₃ from Desulfovibrio vulgaris Miyazaki F have been investigated by NMR and electrochemical methods. The redox potentials of this tetraheme protein are found to be ionic strength-dependent. Especially, the microscopic redox potentials of hemes 2 and 3 at the fourth reduction step increase significantly with increasing ionic strength, which is in contradiction to the theoretical expectation. The coordinated imidazole proton signals are unaffected by ionic strength. However, the methyl and propionate proton signals of hemes 1 and 4 showed significant ionic strength dependencies that are distinct from those for hemes 2 and 3. This heme classification is the same as that found in the ionic strength dependencies of the microscopic redox potentials at the fourth reduction step. Furthermore, the effect of ionic strength on the electrostatic potentials at the heme irons has been examined on the theoretical basis. The electrostatic potential at heme 4 changes up to 1 M ionic strength, which was not expected from the observations reported on cytochromes so far. These results are discussed in connection with the reported anomalous ionic strength dependency of the reduction rate of cytochrome c₃.     

Crystallographic structure of Rhodospirillum molischianum ferricytochrome c' at 2.5 A resolution

This paper describes the 2.5 Å crystallographic structure determination of ferricytochrome c′ from the photosynthetic bacterium Rhodospirillum molischianum. The molecule is a symmetric dimer, with each 128-residue polypeptide chain incorporating a covalently bound protoheme IX prosthetic group. The monomer is structurally organized as an array of four nearly parallel α-helices, which pack most closely at one end and thereafter spatially diverge to accommodate the heme prosthetic group. Although local features of the heme attachment pattern resemble those seen in cytochrome c, the heme iron in cytochrome c′ is pentaco-ordinate with a solvent-exposed histidine residue furnishing the single axial ligand to the heme iron.Subunit association in the dimeric molecule is principally stabilized by helix interactions, which are qualitatively similar to those occurring within each monomer. These interactions result in a dimer geometry that situates the exposed regions of both hemes on the same molecular surface.The structural basis for some of the physiochemical properties cytochrome c′ are examined and compared to those of other heme proteins of known structure.     

Mechanisms of Mitochondrial Holocytochrome c Synthase and the Key Roles Played by Cysteines and Histidine of the Heme Attachment Site,Cys-XX-Cys-His

Mitochondrial cytochrome c assembly requires the covalent attachment of heme by thioether bonds between heme vinyl groups and a conserved CXXCH motif of cytochrome c/c₁. The enzyme holocytochrome c synthase (HCCS) binds heme and apocytochrome c substrate to catalyze this attachment, subsequently releasing holocytochrome c for proper folding to its native structure. We address mechanisms of assembly using a functional Escherichia coli recombinant system expressing human HCCS. Human cytochrome c variants with individual cysteine, histidine, double cysteine, and triple cysteine/histidine substitutions (of CXXCH) were co-purified with HCCS. Single and double mutants form a complex with HCCS but not the triple mutant. Resonance Raman and UV-visible spectroscopy support the proposal that heme puckering induced by both thioether bonds facilitate release of holocytochrome c from the complex. His-19 (of CXXCH) supplies the second axial ligand to heme in the complex, the first axial ligand was previously shown to be from HCCS residue His-154. Substitutions of His-19 in cytochrome c to seven other residues (Gly, Ala, Met, Arg, Lys, Cys, and Tyr) were used with various approaches to establish other roles played by His-19. Three roles for His-19 in HCCS-mediated assembly are suggested: (i) to provide the second axial ligand to the heme iron in preparation for covalent attachment; (ii) to spatially position the two cysteinyl sulfurs adjacent to the two heme vinyl groups for thioether formation; and (iii) to aid in release of the holocytochrome c from the HCCS active site. Only H19M is able to carry out these three roles, albeit at lower efficiencies than the natural His-19.     

The pH dependence of the stereochemistry around the heme group in NO–cytochrome c (horse heart)

The electronic absorption, EPR and MCD spectra of NO derivatives of both ferrous and ferric cytochrome c (horse heart) have been measured in the pH region 2.0 to 12.9, in order to elucidate the pH dependence of the stereochemistry around the heme group. The reaction products of NO with ferrous cytochrome c in equilibrium were as follows: in the region 2.0 ⩽ pH ⩽ 5.3, NO–ferrous cytochrome c; in the region 5.3 < pH ⩽ 11.0, a mixture of NO–ferrous cytochrome c and native ferrous cytochrome c; at pH 12.0, NO–ferrous cytochrome c. At pH 2.0, the NO–ferrous cytochrome c contained a five-coordinate nitrosylheme as the major component and a six-coordinate species as the minor component, and at the order pH values it contained only the six-coordinate species. The reaction products of NO with ferric cytochrome c in equilibrium were as follows: in the region 2.0 ⩽ pH ⩽ 7.2, NO–ferric cytochrome c with six-coordinate nitrosylheme; in the region 7.2 < pH ⩽ 11.0, a mixture of NO–ferrous cytochrome c and native ferrous cytochrome c; at pH 12.0, NO–ferrous cytochrome c. Thus, the reaction of NO with ferric cytochrome c results in the formation of NO–ferrous cytochrome c, which is a typical case of reductive nitrosylation.     

Biochemical and biophysical studies on cytochrome c oxidase XVI. Circular dichroic study of cytochrome c oxidase and its ligand complexes

1. CD spectra of cytochrome c oxidase have been determined both in the absence and presence of the extrinsic ligands CO, NO, cyanide and azide.2. CO and NO affect the CD spectrum of cytochrome c oxidase in a similar way.3. Cyanide and azide also affect the CD spectrum of cytochrome c oxidase in a similar way, but distinctly different from CO and NO.4. From the CD spectra of the oxidized and reduced enzyme, in the presence and absence of extrinsic ligands, CD difference spectra (reduced minus oxidized) are calculated for the so-called cytochrome a and cytochrome a₃ moieties of the enzyme.5. These spectra are largely dependent on the extrinsic ligand used. It is therefore concluded that these spectra do not represent independent cytochrome a and cytochrome a₃ difference spectra, but that heme-heme interactions occur within the cytochrome c oxidase molecule, in such a way that binding of a ligand to one of the heme a groups of cytochrome c oxidase affects the spectral properties of the other heme a group.6. As a consequence, ligand-binding studies cannot give information as to the pre-existence of separate cytochrome a and cytochrome a₃ moieties in the absence of extrinsic ligands.     

Studies on the reaction of imidazole with cytochrome c3 from Desulfovibrio vulgaris

1. Cytochrome c₃, a unique hemoprotein with a negative redox potential and four heme groups bound to a single polypeptide chain, reacts with imidazole in the reduced state to form a low-spin ferro · imidazole complex which is spectrally characterized by a 3.1 nm blue shift in the α-peak (from 550.5 to 547.4 nm). The spectral imidazole · cytochrome c₃ complex is detectable at 77 but not at 298 K.2. Mammalian ferrocytochrome c did not undergo a spectral interaction with imidazole at either 77 or 298 K, indicating that the imidazole · cytochrome c₃ complex reflects a unique event for cytochrome c₃.3. Formation of the imidazole · cytochrome c₃ complex is strongly dependent on imidazole concentration (apparent K_d of approx. 50 mM), and is abolished in the presence of 100 mM phosphate. This latter effect is attributable to formation of an imidazole · phosphate complex. A pH titration of the imidazole · cytochrome c₃ spectral complex implicates ionization of an imidazole function (pK = 8.5).4. EPR studies at 8.5 K of ferricytochrome c₃ before and after one reduction-oxidation cycle indicate that at least two of the hemes undergo reaction with imidazole forming two different low-spin ferric heme · imidazole complexes, with significant shifts in the g values of two heme signals.5. The spectral and EPR results are consistent with formation as the primary event of a low-spin ferrocytochrome c₃ · imidazole complex in which increased hydrophobicity and protonation-deprotonation effects are contributary to the consequent lability of cytochrome c₃.     

Structure of cytochrome c551 from Pseudomonas aeruginosa refined at 1.6 Å resolution and comparison of the two redox forms

The molecular structures of ferri- and ferrocytochrome c₅₅₁ from Pseudomonas aeruginosa have been refined at a resolution of 1.6 Å, to an R factor of 19.5% for the oxidized molecule and 18.7% for the reduced. Reduction of oxidized crystals with ascorbate produced little change in cell dimensions, a 10% mean change in F_obs, and no damage to the crystals. The heme iron is not significantly displaced from the porphyrin plane. Bond lengths from axial ligands to the heme iron are as expected in a low-spin iron compound. A total of 67 solvent molecules were incorporated in the oxidized structure, and 73 in the reduced, of which four are found inside the protein molecule. The oxidized and reduced forms have virtually identical tertiary structures with 2 ° root-mean-square differences in main-chain torsion angles φ and ψ, but with larger differences along the two edges of the heme crevice. The difference map and pyrrole ring tilt suggest that a partially buried water molecule (no. 23) in the heme crevice moves upon change of oxidation state.Pseudomonas cytochrome c₅₅₁ differs from tuna cytochrome c in having: (1) a water molecule (no. 23) at the upper left of the heme crevice; that is, between Pro62 and the heme pyrrol 3 ring on the sixth ligand Met61 side, where tuna cytochrome c has an evolutionary invariant Phe82 ring; (2) a string of hydrophobic side-chains along the left side of the heme crevice, and fewer positively charged lysines in the vicinity; and (3) a more exposed and presumably more easily ionizable heme propionate group at the bottom of the molecule. A network of hydrogen bonds in the heme crevice is reminiscent of that inside the heme crevice of tuna cytochrome c. As in tuna, a slight motion of the water molecule toward the heme is observed in the oxidized state, helping to give the heme a more polar microenvironment. The continuity of solvent environment between the heme crevice and the outer medium could explain the greater dependence of redox potential on pH in cytochrome c₅₅₁ than in cytochrome c.     

Kinetic and equilibrium studies of acrylonitrile binding to cytochrome c peroxidase and oxidation of acrylonitrile by cytochrome c peroxidase compound I

Ferric heme proteins bind weakly basic ligands and the binding affinity is often pH dependent due to protonation of the ligand as well as the protein. In an effort to find a small, neutral ligand without significant acid/base properties to probe ligand binding reactions in ferric heme proteins we were led to consider the organonitriles. Although organonitriles are known to bind to transition metals, we have been unable to find any prior studies of nitrile binding to heme proteins. In this communication we report on the equilibrium and kinetic properties of acrylonitrile binding to cytochrome c peroxidase (CcP) as well as the oxidation of acrylonitrile by CcP compound I. Acrylonitrile binding to CcP is independent of pH between pH 4 and 8. The association and dissociation rate constants are 0.32 ± 0.16 M⁻¹ s⁻¹ and 0.34 ± 0.15 s⁻¹, respectively, and the independently measured equilibrium dissociation constant for the complex is 1.1 ± 0.2 M. We have demonstrated for the first time that acrylonitrile can bind to a ferric heme protein. The binding mechanism appears to be a simple, one-step association of the ligand with the heme iron. We have also demonstrated that CcP can catalyze the oxidation of acrylonitrile, most likely to 2-cyanoethylene oxide in a “peroxygenase”-type reaction, with rates that are similar to rat liver microsomal cytochrome P450-catalyzed oxidation of acrylonitrile in the monooxygenase reaction. CcP compound I oxidizes acrylonitrile with a maximum turnover number of 0.61 min⁻¹ at pH 6.0.     

Proton nuclear-magnetic-resonance and resonance Raman studies of thermophilic cytochrome c-552 from Thermus thermophilus HB8

The pH and temperature dependences of the 270-MHz proton nuclear magnetic resonance and resonance Raman spectra of Thermus thermophilus cytochrome c-552 were studied. Observation of the NMR methyl signal of the iron-bound methionine indicates that a methionine residue is the sixth ligand of heme iron in both ferric and ferrous states, although the environment of this methionine is not similar to that in mitochondrial cytochrome c. The NMR methyl signal of the coordinated methionine in the ferrous state was observed even at 87 degrees C, indicating the retention of the methionine ligand at the sixth coordination position. None of resonance Raman lines in ferrous cytochrome c-552 at higher temperatures showed a prominant temperature-dependent frequency shift, which implies that the heme iron was still bound with strong ligands and retained the low-spin state. In either redox state overall thermal denaturation did not occur even at 87 degrees C, although the ferric form existed in thermal spin mixture of the low-spin and high-spin species at higher temperatures. The hyperfine-shifted NMR resonances of the ferric form indicated rapid exchange of the sixth ligand at alkaline pH in the process of a single-step alkaline isomerization.     

The influence of pH on the EPR and redox properties of cytochrome c oxidase in detergent solution and in phospholipid vesicles

The EPR signals of oxidized and partially reduced cytochrome oxidase have been studied at pH 6.4, 7.4, and 8.4. Isolated cytochrome oxidase in both non-ionic detergent solution and in phospholipid vesicles has been used in reductive titrations with ferrocytochrome c.The g values of the low- and high-field parts of the low-spin heme signal in oxidized cytochrome oxidase are shown to be pH dependent. In reductive titrations, low-spin heme signals at g 2.6 as well as rhombic and nearly axial high-spin heme signals are found at pH 8.4, while the only heme signals appearing at pH 6.4 are two nearly axial g 6 signals. This pH dependence is shifted in the vesicles.The g 2.6 signals formed in titrations with ferrocytochrome c at pH 8.4 correspond maximally to 0.25–0.35 heme per functional unit (aa₃) of cytochrome oxidase in detergent solution and to 0.22 heme in vesicle oxidase. The total amount of high-spin heme signals at g 6 found in partially reduced enzyme is 0.45–0.6 at pH 6.4 and 0.1–0.2 at pH 8.4. In titrations of cytochrome oxidase in detergent solution the g 1.45 and g 2 signals disappear with fewer equivalents of ferrocytochrome c added at pH 8.4 compared to pH 6.4.The results indicate that the environment of the hemes varies with the pH. One change is interpreted as cytochrome a₃ being converted from a high-spin to a low-spin form when the pH is increased. Possibly this transition is related to a change of a liganded H₂O to OH^? with a concomitant decrease of the redox potential. Oxidase in phosphatidylcholine vesicles is found to behave as if it experiences a pH, one unit lower than that of the medium.     

1H nmr studies of complexes of ferric leghemoglobin with substituted pyridines and nicotinic acids

The ¹H nuclear magnetic resonance (nmr) spectra of complexes of soybean ferric leghemoglobin with 3-substituted pyridines and 5-substituted nicotinic acids have been recorded in order to determine the influence of axial ligands on heme electronic structure. The hyperfine shifted resonances of the heme group were assigned by analogy to previous assignments for the pyridine and nicotinic acid complexes of leghemoglobin. The spectra are characteristic of predominantly low-spin ferric heme complexes. For the pyridine complexes, the rate of ligand exchange was found to increase with decreasing ligand pK_A. For many of the complexes, optical and nmr spectra reveal the presence of an equilibrium mixture of high- and low-spin states of the iron atom. The percentage of high-spin component increases with decreasing ligand pK_A Smaller hyperfine shifts are noted for leghemoglobin complexes with ligands capable of weak ligand → metal π bonding. The pattern of hyperfine shifted resonances is similar for all complexes studied and indicates that the overall heme electronic structure is dominated by the bonding to the proximal histidine.     

Structural Evidence for the Functional Importance of the Heme Domain Mobility in Flavocytochrome b2

Yeast flavocytochrome b₂ (Fcb2) is an l-lactate:cytochrome c oxidoreductase in the mitochondrial intermembrane space participating in cellular respiration. Each enzyme subunit consists of a cytochrome b₅-like heme domain and a flavodehydrogenase (FDH) domain. In the Fcb2 crystal structure, the heme domain is mobile relative to the tetrameric FDH core in one out of two subunits. The monoclonal antibody B2B4, elicited against the holoenzyme, recognizes only the native heme domain in the holoenzyme. When bound, it suppresses the intramolecular electron transfer from flavin to heme b₂, hence cytochrome c reduction. We report here the crystal structure of the heme domain in complex with the Fab at 2.7 Å resolution. The Fab epitope on the heme domain includes the two exposed propionate groups of the heme, which are hidden in the interface between the domains in the complete subunit. The structure discloses an unexpected plasticity of Fcb2 in the neighborhood of the heme cavity, in which the heme has rotated. The epitope overlaps with the docking area of the FDH domain onto the heme domain, indicating that the antibody displaces the heme domain in a movement of large amplitude. We suggest that the binding sites on the heme domain of cytochrome c and of the FDH domain also overlap and therefore that cytochrome c binding also requires the heme domain to move away from the FDH domain, so as to allow electron transfer between the two hemes. Based on this hypothesis, we propose a possible model of the Fcb2·cytochrome c complex. Interestingly, this model shares similarity with that of the cytochrome b₅·cytochrome c complex, in which cytochrome c binds to the surface around the exposed heme edge of cytochrome b₅. The present results therefore support the idea that the heme domain mobility is an inherent component of the Fcb2 functioning.     

Quinol oxidation by c-type cytochromes: structural characterization of the menaquinol binding site of NrfHA

Membrane-bound cytochrome c quinol dehydrogenases play a crucial role in bacterial respiration by oxidizing menaquinol and transferring electrons to various periplasmic oxidoreductases. In this work, the menaquinol oxidation site of NrfH was characterized by the determination of the X-ray structure of Desulfovibrio vulgaris NrfHA nitrite reductase complex bound to 2-heptyl-4-hydroxyquinoline-N-oxide, which is shown to act as a competitive inhibitor of NrfH quinol oxidation activity. The structure, at 2.8-Å resolution, reveals that the inhibitor binds close to NrfH heme 1, where it establishes polar contacts with two essential residues: Asp89, the residue occupying the heme distal ligand position, and Lys82, a strictly conserved residue. The menaquinol binding cavity is largely polar and has a wide opening to the protein surface. Coarse-grained molecular dynamics simulations suggest that the quinol binding site of NrfH and several other respiratory enzymes lie in the head group region of the membrane, which probably facilitates proton transfer to the periplasm. Although NrfH is not a multi-span membrane protein, its quinol binding site has several characteristics similar to those of quinone binding sites previously described. The data presented here provide the first characterization of the quinol binding site of the cytochrome c quinol dehydrogenase family.