Conformation-dependent participation of the protein in electron equivalent transfer to cytochrome c.

When ferricytochrome c is reduced by H atoms (produced by pulse radiolysis) at neutral pH where it is in a closed protein configuration, a considerable percentage of the reduction proceeds through electron equivalent transfer via the protein. At pH 2.0, where cytochrome c is in an open configuration, H atoms reduce by adding directly to the heme porphyrin. The intermediate then observed is identified through similarity with that formed on ferriheme alone.     

Structural Basis for Cytochrome c Y67H Mutant to Function as a Peroxidase

The catalytic activity of cytochrome c (cyt c) to peroxidize cardiolipin to its oxidized form is required for the release of pro-apoptotic factors from mitochondria, and for execution of the subsequent apoptotic steps. However, the structural basis for this peroxidation reaction remains unclear. In this paper, we determined the three-dimensional NMR solution structure of yeast cyt c Y67H variant with high peroxidase activity, which is almost similar to that of its native form. The structure reveals that the hydrogen bond between Met80 and residue 67 is disrupted. This change destabilizes the sixth coordination bond between heme Fe³⁺ ion and Met80 sulfur atom in the Y67H variant, and further makes it more easily be broken at low pH conditions. The steady-state studies indicate that the Y67H variant has the highest peroxidase activities when pH condition is between 4.0 and 5.2. Finally, a mechanism is suggested for the peroxidation of cardiolipin catalyzed by the Y67H variant, where the residue His67 acts as a distal histidine, its protonation facilitates O-O bond cleavage of H₂O₂ by functioning as an acidic catalyst.     

A deuteron and proton magnetic resonance relaxation study of beta-lactoglobulin a association: some approaches to the Scatchard hydration of globular proteins

A general expression for the concentration-dependent relaxation increment, $\text{(}\text{dR}\text{dc}\text{)}{}_{\mathrm{\mu }}$, (where R may be R₁, the spin-lattice, or R₂, the spin-spin relaxation rate of water), has been derived from multicomponent theory for a protein in salt solution. Emphasis is placed on the addition of salt to the aqueous protein to minimize potentially high virial effects due to charge repulsion or to the charge fluctuations predicted by the Kirkwood-Shumaker theory; under conditions where the protein has a high net charge-to-mass ratio the calculation of relaxation increments must employ protein activities in place of concentrations. This treatment was applied to the molecular states of β-lactoglobulin A under associating and nonassociating conditions. In contrast to data in the literature obtained in the absence of salt, where correlation times τ_c were excessively high and hydration values too low, here values of τ_c from ²H NMR were in quantitative agreement with those expected from parameters of the known structural states of this protein. With these values, hydrations were obtained by three different ways of calculating the relaxation rate of the bound water from ¹H and ²H NMR data. Preferential hydrations, derived from linked functions, for the association of the protein at pH 4.65 were obtained from sedimentation velocity measurements. Combination of the results from the temperature dependence of the deuteron NMR and the linked functions, on the basis of a three-state model, yields slow-tumbling hydration values and correlation times comparable to those obtained from the two-state model. Based on either an isotropic bound-water mechanism or an anisotropic orientational distribution of the water molecules, enthalpies of hydration determined from the three-state model are in accord with those calculated from the two-state model.     

Crystal structure of cytochrome c' from Rhodocyclus gelatinosus and comparison with other cytochromes c'

Cytochromes c' are heme proteins found in photosynthetic and denitrifying bacteria, where they are presumably involved in electron transport. The cytochrome c' isolated from the bacterium Rhodocyclus gelatinosus (RGCP) forms a homodimer with each polypeptide containing 129 residues. It has been crystallised in ammonium sulfate at pH?6. Crystals belong to space group P3₁21 with cell parameters a?=?70.2?Å and c?=?126.8?Å, which corresponds to a dimer in the asymmetric unit (VM?=?3.5?ų?/?Da). The crystal structure of RGCP was solved by the molecular replacement method and refined using data to 2.5-Å resolution. The final crystallographic R factor was 17.9% for all reflections (above 2?σ) in the resolution range 27.4 to 2.5?Å. The refined model includes 1876 non-hydrogen protein atoms and 56 water molecules. As typical of c–type cytochromes, the heme group is covalently bound to Cys-X-Y-Cys-His through thio-ether bonds, and His123 occupies the fifth axial coordination position. On the vacant "distal" site, Phe16 blocks the direct access to the sixth coordination site, which is in a predominantly hydrophobic environment. In spite of the low sequence homology among cytochromes c' the overall fold is similar. The monomer structure consists of 4 anti-parallel α-helices and has random coils in the loops between the helices, and at the N- and C-termini. The subunits cross each other to form an X shape.     

Structure analysis and characterization of the cytochrome c-554 from thermophilic green sulfur photosynthetic bacterium Chlorobaculum tepidum

The cytochrome (Cyt) c-554 in thermophilic green photosynthetic bacterium Chlorobaculum tepidum serves as an intermediate electron carrier, transferring electrons to the membrane-bound Cyt c _z from various enzymes involved in the oxidations of sulfide, thiosulfate, and sulfite compounds. Spectroscopically, this protein exhibits an asymmetric α-absorption band for the reduced form and particularly large paramagnetic ¹H NMR shifts for the heme methyl groups with an unusual shift pattern in the oxidized form. The crystal structure of the Cyt c-554 has been determined at high resolution. The overall fold consists of four α-helices and is characterized by a remarkably long and flexible loop between the α3 and α4 helices. The axial ligand methionine has S-chirality at the sulfur atom with its C^εH₃ group pointing toward the heme pyrrole ring I. This configuration corresponds to an orientation of the lone-pair orbital of the sulfur atom directed at the pyrrole ring II and explains the lowest-field ¹H NMR shift arising from the 18¹ heme methyl protons. Differing from most other class I Cyts c, no hydrogen bond was formed between the methionine sulfur atom and polypeptide chain. Lack of this hydrogen bond may account for the observed large paramagnetic ¹H NMR shifts of the heme methyl protons. The surface-exposed heme pyrrole ring II edge is in a relatively hydrophobic environment surrounded by several electronically neutral residues. This portion is considered as an electron transfer gateway. The structure of the Cyt c-554 is compared with those of other Cyts c, and possible interactions of this protein with its electron transport partners are discussed.     

Cyanide-linked dimer-monomer equilibrium of Chromatium vinosum ferric cytochrome c′

Cyanide binding to Chromatium vinosum ferricytochrome c′ has been studied to further investigate possible allosteric interactions between the subunits of this dimeric protein. Cyanide binding to C. vinosum cytochrome c′ appears to be cooperative. However, the cyanide binding reaction is unusual in that the overall affinity of cyanide increases as the concentration of cytochrome c′ decreases and that cyanide binding causes the ligated dimer to dissociate to monomers as shown by gel-filtration chromatography. Therefore, the cyanide binding properties of C. vinosum ferricytochrome c′ are complicated by a cyanide-linked dimer to monomer dissociation equilibrium of the complexed protein. The dimer to monomer dissociation constant is 20-fold smaller than that for CO linked dissociation constant of ferrocytochrome c′. Furthermore, the pH dependence of both the intrinsic equilibrium binding constant and the dimer to monomer equilibrium dissociation constant was investigated over the pH range of 7.0 to 9.2 to examine the effect of any ionizable groups. The equilibrium constants did not exhibit a significant pH dependence over this pH range.     

Laser Raman spectroscopy of lipid-protein systems Differences in the effect of intrinsic and extrinsic proteins on the phosphatidylcholine Raman spectrum

Laser Raman spectroscopy is used to examine the interactions of intrinsic and extrinsic proteins with the lipid layer structure. The interactions of cytochrome c and cytochrome c oxidase with lipids have been well established by others using a variety of techniques. Cytochrome c is thought to act as an extrinsic membrane protein while cytochrome c oxidase is thought to act as an intrinsic membrane protein. The lipid-cytochrome c and lipid cytochrome c oxidase systems are used to assist in interpreting the spectral changes due to extrinsic and intrinsic protein interactions. The two types of proteins examined produced differential changes in the lipid hydrocarbon CH stretch Raman modes for both dimyristoyl and dipalmitoyl phosphatidylcholine. The plasma proteins albumin and fibrinogen were also found to differentially affect the lipid hydrocarbon CH stretch Raman modes. These proteins appear to interact with lipids in an extrinsic manner different from that of cytochrome c.     

Accommodation of NO in the active site of mammalian and bacterial cytochrome c oxidase aa3

Following different reports on the stoichiometry and configuration of NO binding to mammalian and bacterial reduced cytochrome c oxidase aa₃ (CcO), we investigated NO binding and dynamics in the active site of beef heart CcO as a function of NO concentration, using ultrafast transient absorption and EPR spectroscopy. We find that in the physiological range only one NO molecule binds to heme a₃, and time-resolved experiments indicate that even transient binding to Cu_B does not occur. Only at very high (∼ 2 mM) concentrations a second NO is accommodated in the active site, although in a different configuration than previously observed for CcO from Paracoccus denitrificans [E. Pilet, W. Nitschke, F. Rappaport, T. Soulimane, J.-C. Lambry, U. Liebl and M.H. Vos. Biochemistry 43 (2004) 14118-14127], where we proposed that a second NO does bind to Cu_B. In addition, in the bacterial enzyme two NO molecules can bind already at NO concentrations of ∼ 1 μM. The unexpected differences highlighted in this study may relate to differences in the physiological relevance of the CcO-NO interactions in both species.     

Characterization of the iron-sulfur protein of the mitochondrial outer membrane partially purified from beef kidney cortex

The iron-sulfur protein present in the mitochondrial outer membrane has been partially purified from beef kidney cortex mitochondria be means of selective solubilization followed by DEAE-cellulose chromatography. The EPR spectrum of the iron-sulfur protein with g-values at 2.01, 1.94 and 1.89 was well resolved up to 200 K which is unusual for an iron-sulfur protein. Analyses confirmed a center with two iron and two labile sulfur atoms in the protein. By measuring the effect of oxidation-reduction potential on the EPR signal amplitude, midpoint potentials at pH 7.2 were determined both for the purified ironsulfur protein, +75 (±5) mV, and in prepared mitochondrial outer membrane, +62 (±6) mV. At pH 8.2 slightly lower values were indicated, +62 and 52 mV, respectively. The oxidation-reduction equilibrium involved a one electron transfer. A functional relationship to the rotenone-insensitive NADH-cytochrome c oxidoreductase in the mitochondrial outer membrane is suggested. Both this activity and the iron-sulfur center were sensitive to acidities slightly below pH 7 in contrast to the iron-sulfur centers of the inner membrane.     

Trichodiene biosynthesis and the stereochemistry of the enzymatic cyclization of farnesyl pyrophosphate

Cyclization of trans,trans-[1-³H₂,12,13-¹⁴C]farnesyl pyrophosphate (2a) by a preparation of trichodiene synthetase isolated from the fungus, Trichothecium roseum, gave trichodiene (5a), which was shown by chemical degradation to retain both tritium atoms of the precursor at C-11. Incubation of 1S-[1-³H,12,13-¹⁴C]farnesyl pyrophosphate (2b) and 1R-[1-³H,12,13-¹⁴C]farnesyl pyrophosphate (2c) with trichodiene synthetase and degradation of the resulting labeled trichodienes, 5b and 5c, established that the displacement of the pyrophosphate moiety from C-1 of the precursor and formation of the new C-C bond in the formation of trichodiene takes place with net retention of configuration. These results are accounted for by an isomerization-cyclization mechanism involving the intermediacy of nerolidyl pyrophosphate (4).     

Role of the active-site cysteine of Pseudomonas aeruginosa azurin. Crystal structure analysis of the CuII(Cys112Asp) protein

Replacement of the cysteine at position 112 of Pseudomonas aeruginosa azurin with an aspartic acid residue results in a mutant (Cys112Asp) protein that retains a strong copper-binding site. Cu^II(Cys112Asp) azurin can be reduced by excess [Ru^II(NH₃)₆]²⁺, resulting in a Cu^I protein with an electronic absorption spectrum very similar to that of wild-type Cu^I azurin. Cys112Asp azurin exhibits reversible interprotein electron-transfer reactivity with P. aeruginosa cytochrome c ₅₅₁ (μ?=?0.1?M sodium phosphate (pH?7.0);E°(Cu^II/I)?=?180 mV vs NHE); this redox activity indicates that electrons can still enter and exit the protein through the partially solvent-exposed imidazole ring of His117. The structure of Cu^II(Cys112Asp) azurin at 2.4-Å resolution shows that the active-site copper is five coordinate: the pseudo-square base of the distorted square-pyramidal structure is defined by the imidazole N^δ atoms of His46 and His117 and the oxygen atoms of an asymmetrically-bound bidentate carboxylate group of Asp112; the apical position is occupied by the oxygen atom of the backbone carbonyl group of Gly45. The Cu^II–Asp112 interaction is distinguished by an approximately 1.2-Å displacement of the metal center from the plane defined by the Asp112 carboxylate group.     

The reaction of Euglena gracilis cytochrome c-552 with nonphysio-logical oxidants and reductants.

The reaction of Euglena gracilis cytochrome c-552 (cytochrome f) with the nonphysiological reactants potassium ferrocyanide, potassium ferricyanide, sodium ascorbate, sodium dithionite, and Chromatium vinosum high potential nonheme iron protein was studied by stopped-flow and temperature-jump kinetic methods. The reaction of the purified, water-soluble protein with the reactants was investigated as a function of ionic strength, pH, and temperature. The results demonstrated that reduction and oxidation takes place at a negatively charged site on the cytochrome c-552 surface. Participation of specific amino acid residues in electron transfer is implicated from the pH results. The results obtained for the nonphysiological reactions of cytochrome c-552 are compared with available data for horse heart cytochrome c and Rhodospirillum rubrum cytochrome c₂. The results strongly suggest that Euglena gracilis cytochrome c-552 undergoes nonphysiological oxidation and reduction by a mechanism different from that found for cytochrome c or cytochrome c₂.     

Methionine-oxidized horse heart cytochromes c. II. Conformation and heme configuration

The two products from the reaction of horse heart ferricytochrome c with Chloramine-T, the F^III and F^II CT-cytochromes, contain modification of the methionines to methionine sulfoxides, but they are distinct in their physiological functions. Conformational and heme-configurational characterization of the two CT-cytochromes has been carried out by using absorption, circular dichroism, fluorescence, proton magnetic resonance, and resonance Raman spectroscopy. The pH-absorption spectroscopic behavior, thermal stability, and ionization of the phenolic hydroxyls have also been reported. Spectroscopic studies of the heme c fragment, H8, in the presence of dimethylsulfoxide, as a model for CT-cytochrome heme configuration, were also conducted. The ferric and the ferrous CT-cytochromes above pH 7.5 have similar, yet distinct, spectroscopic properties, absorption, CD, resonance Raman, and PMR spectra, typical of low-spin hexacoordinated hemes, but distinct from those of the unmodified protein. The ferric spectrum lacks the 695-nm band, and the reduced spectrum contains an additional inflection at about 400 nm, a feature also observed in the spectra of ferrous H8-DMSO systems. The CD, resonance Raman, and PMR spectra are typical of a cytochrome with a loosened heme crevice and altered coordination configuration. The Methionine-80 proton resonances are absent in the uupfield PMR spectra of both the CT-ferricytochromes. The ferrous spectra, on the other hand, contain all the Met-80 resonances, but with smaller upfield shifts than those of the native protein. Both CT-ferric cytochromes are less stable in the acid region and convert to high-spin forms with a two-step transition and with a distinct set of pK _a values. The overall conformation is nearly identical to that of the native protein, but it is less stable to thermal unfolding. All the factors differentiating the modified preparations from the unmodified protein are more pronunced in the case of F^II, with F^III being the closest to the unmodified form. The two functionally distinct CT-cytochromes are two conformational isomers; conformationally and heme configurationally, they are spectroscopically very similar, yet distinct. Both contain an altered heme iron coordination configuration. The sulfur of Met-80 is repalced by the oxygen of Met-80 sulfoxide of a different configuration, R or S. Both contain a loosened heme crevice and are conformationally less stable than the native protein, F^II CT-cytochrome c being the most deranged.     

The role of a disulfide bridge in the stability and folding kinetics of Arabidopsis thaliana cytochrome c6A

Cytochrome c_6A is a eukaryotic member of the Class I cytochrome c family possessing a high structural homology with photosynthetic cytochrome c₆ from cyanobacteria, but structurally and functionally distinct through the presence of a disulfide bond and a heme mid-point redox potential of + 71 mV (vs normal hydrogen electrode). The disulfide bond is part of a loop insertion peptide that forms a cap-like structure on top of the core α-helical fold. We have investigated the contribution of the disulfide bond to thermodynamic stability and (un)folding kinetics in cytochrome c_6A from Arabidopsis thaliana by making comparison with a photosynthetic cytochrome c₆ from Phormidium laminosum and through a mutant in which the Cys residues have been replaced with Ser residues (C67/73S). We find that the disulfide bond makes a significant contribution to overall stability in both the ferric and ferrous heme states. Both cytochromes c_6A and c₆ fold rapidly at neutral pH through an on-pathway intermediate. The unfolding rate for the C67/73S variant is significantly increased indicating that the formation of this region occurs late in the folding pathway. We conclude that the disulfide bridge in cytochrome c_6A acts as a conformational restraint in both the folding intermediate and native state of the protein and that it likely serves a structural rather than a previously proposed catalytic role.     

Equilibrium and kinetic measurements of the redox potentials of cytochromes c2 in vitro and in vivo

The equilibrium oxidation-reduction mipoint potential (E_m) of isolated Rhodopseudomonas sphaeroides cytochrome c₂ exhibits a pH-dependent behavior which can be ascribed to a pK on the oxidized form at pH 8.0 (Pettigrew et al. (1975) Biochim. Biophys. Acta 430, 197–208). However, as with mammalian cytochrome c (Brandt, K.G., Parks, P.C., Czerlinski, G.H. and Hess, G.P. (1966) J. Biol. Chem. 241, 4180–4185) this pK can more properly be attributed to the combination of a pK beyond pH 11, and a slow conformational change of the ferricytochrome. This has been demonstrated by resolving the E_m of cytochrome c₂ before and after the conformational change. The E_m of the unaltered form is essentially pH independent between pH 7 and 11.5, and the lower equilibrium E_m is due solely to the conformational change. In vivo the conformational change is prevented by the binding of the cytochrome c₂ to the photochemical reaction center, and the cytochrome exhibits an essentially pH-independent E_m from pH 5 to 11. The alkaline transition thus has little physiological significance, and it is unlikely that the redox reactions of cytochrome c₂ in vivo involve protons.     

The oxidation-reduction kinetics of the reaction of cytochrome c1 with non-physiological redox agents

The kinetics of the oxidation-reduction reactions of cytochrome c₁ with ascorbate, ferricyanide, triphenanthrolinecobalt(III) and N,N,N′,N′-tetramethyl-p-phenylenediamine (TMPD) have been examined using the stopped-flow technique. The reduction of ferricytochrome c₁ by ascorbic acid is investigated as a function of pH. It is shown that at neutral and alkaline pH the reduction of the protein is mainly performed by the doubly deprotonated form of ascorbate. From the ionic-strength-dependence studies of the reactions of cytochrome c₁ with ascorbate, ferricyanide and triphenanthrolinecobalt(III), it is demonstrated that the reaction rate is governed by electrostatic interactions. The second-order rate constants for the reaction of cytochrome c₁ with ascorbate, ferricyanide, TMPD and triphenanthrolinecobalt(III) are 1.4·10⁴, 3.2·10³, 3.8·10⁴ and 1.3·10⁸ M^?1·s^?1 (pH 7.0, I = 0, 10°C), respectively. Application of the Debye-Hückel theory to the the ionic-strength-dependence studies of these redox reactions of cytochrome c₁ yielded for ferrocytochrome c₁ and ferricytochrome c₁ a net charge of ?5 and ?4, respectively. The latter value is close to that of ?3 for the oxidized enzyme, calculated from the amino acid sequence of the protein. This implies that not a local charge on the surface of the protein, but the overall net charge of cytochrome c₁ governs the reaction rate with small redox molecules.     

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.     

Saturation transfer electron paramagnetic resonance spectroscopy of spin labeled tobacco mosaic virus protein.

The coat protein of Tobacco Mosaic Virus is covalently labeled with a maleimide spin label at the single SH-group of the protein. Saturation transfer electron paramagnetic resonance spectroscopy, a technique that is sensitive to very slow molecular motion with rotational correlation times τ_c in the range 10^?7 to 10^?3 sec, shows the dissociation of large oligomers of spin labeled protein with τ_c～10^?4 sec at pH 5.5 to smaller oligomers at higher pH.     

Kinetic study of isomerization of ferricytochrome c at alkaline pH

Kinetic studies of the isomerization reaction of horse heart ferricytochrome c between pH 8.5 and pH 12.1 have been carried out by using stopped-flow and rapid scanning stopped-flow techniques. Below pH 10, our results were in good agreement with the scheme proposed earlier (Davis, L. A., Schejter, A. and Hess, G. P. (1974) J. Biol. Chem. 249, 2624–2632). Above pH 10, another faster first-order process was observed, which suggested the existence of a transient species in the isomerization reaction between the species with and without a 695 nm band. The probable scheme of the isomerization reaction is considered to be

where H denotes a proton, the colored forms are the species predominant at neutral pH with a 695 nm band and the noncolored forms are the species without a 695 nm band. The transient species has a small 695 nm absorbance which suggests that the sixth ligand is still Met-80, although the protein conformation might be different from that at neutral pH.