Reduction of ferricytochrome c by tyrosyltyrosylphenylalanine

Cytochrome c (cyt c) was reduced by a tyrosine-containing peptide, tyrosyltyrosylphenylalanine (TyrTyrPhe), at pH 6.0–8.0, while tyrosinol or tyrosyltyrosine (TyrTyr) could not reduce cyt c effectively under the same condition. Cyt c was reduced at high peptide concentration, whereas the reaction did not occur effectively at low concentration. The reaction rate varied with time owing to a decrease in the TyrTyrPhe concentration and the production of tyrosine derivatives during the reaction. The initial rate constants were 2.4×10^–4 and 8.1×10^–4 s^–1 at pH 7.0 and 8.0, respectively, for the reaction with 1.0 mM TyrTyrPhe in 10 mM phosphate buffer at 15°C. The reciprocal initial rate constant (1/k_int) increased linearly against the reciprocal peptide concentration and against the linear proton concentration, whereas logk_int decreased linearly against the root of the ionic strength. These results show that deprotonated (TyrTyrPhe)^–, presumably deprotonated at a tyrosine site, reduces cyt c by formation of an electrostatic complex. No significant difference in the reaction rate was observed between the reaction under nitrogen and oxygen atmospheres. From the matrix-assisted laser desorption ionization time-of-flight mass spectra of the reaction products, formation of a quinone and other tyrosine derivatives of the peptide was supported. These products should have been produced from a tyrosyl radical. We interpret the results that a cyt c_ox/(TyrTyrPhe)^–cyt c_red/(TyrTyrPhe) equilibrium is formed, which is usually shifted to the left. This equilibrium may shift to the right by reaction of the produced tyrosyl radical with the tyrosine sites of unreacted TyrTyrPhe peptides.     

Reaction of cythchrome c with one-electron redox reagents. I. Reduction of ferricytochrome c by the hydrated electron produced by pulse radiolysis

Pulse radiolysis-kinetic spectrometry has been used to investigate the reaction of hydrated electrons with ferricytochrome c in dilute aqueous solution at pH 6.5–7.0. Time resolutions from 2·10^?7 to 1 s were employed. Transient spectra from 320 to 580 nm were characterized with a wavelength resolution of ±0.5 nm. 1 In neutral salt-free solution, k(ferricytochrome c+e^?_aq)=(6.0±0.9)·10¹⁰ M^?1·s^?1 and k(ferricytochrome c+H)=(1.2±0.2)·10¹⁰ M^?1·s^?1. The reaction of ferricytochrome c with hydrated electrons is sensitive to ionic strength; in 0.1 M NaClO₄, k(ferricytochrome c+e^?_aq)=(2.4±0.4)·10¹⁰ M^?1·s^?1. In contrast, k(ferricytochrome c+H) is insensitive to ionic strength. Time resolution of three spectral stages has been accomplished. The primary spectrum is the first observable spectrum detectable after irradiation and is formed in a second-order process. Its rate of formation is indisting-uishable from the rate of disappearance of the electron spectrum. The secondary spectrum is generated in a true first order intramolecular process, k(p→s)=(1.2±0.1)·10⁵ s^?1. The tertiary spectrum is also generated in a true first-order process, k(s→t)=(1.3±0.2)·10² s^?1. The specific rates of both transformations are independent of the wavelength of measurement. The tertiary spectrum, observable 50 ms after initial reaction and remaining unchanged thereafter for at least 1 s, shows that relaxed ferrocytochrome c is the only detectable product. This product is not autoxidizable, as expected for native reduced enzyme. It is more probable that the intramolecular changes responsible for the p→s and s→t spectral transformations involve the influence of conformational relaxation of ferrocytochrome c upon electronic energy states then that they are intramolecular transmission of reducing equivalents from primary sites of electron attachment.     

Evolutionary change of the heme c electronic structure: ferricytochrome c-551 from Pseudomonas aeruginosa and horse heart ferricytochrome c.

Individual assignments of the ¹H n.m.r. lines of heme c in reduced and oxidized cytochrome c-551 from $\text{Pseudomonas aeruginosa}$ were obtained by nuclear Overhauser enhancement and saturation transfer experiments. Comparison with the corresponding data on horse heart cytochrome c showed that the locations of high spin density on the heme c periphery as well as the in-plane principal axes x and y of the electronic g-tensor are rotated by approximately 90° in ferricytochrome c-551 relative to horse ferricytochrome c. High spin density in ferricytochrome c-551 is thus localized on the pyrrole ring III. While this pyrrole ring is well shielded in the interior of mammalian-type cytochromes c, it is more easily accessible in cytochrome c-551. It is suggested that this evolutionary change of the heme c electronic structure would be compatible with the hypothesis that the electron transfer in both species is via solvent exposed peripheral ring carbon atoms.     

Structural and thermodynamic behavior of cytochrome c assembled with glutathione-covered gold nanoparticles

The conformational changes of horse heart ferricytochrome c (cyt c) after association of gold nanoparticles have been studied by electronic absorption spectroscopy and circular dichroism (CD). Our results show that the structural stability around the heme of complexed cyt c was increased successfully. Glutathione-layered gold nanoparticles caused a significant increase of the apparent pK values of the cyt c alkaline transition. Similarly, the heme crevice became more stable to heat after assembly of cyt c with gold nanoparticles. In contrast, gold nanoparticles weaken the overall thermal stability of the cyt c by decreasing the denaturation temperature estimated from far-UV CD measurements. Similar behavior has previously been reported for cyt c complexed with physiological redox partners as well as hydrophilic polyanions. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

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.     

Relation of the structure and function of ferricytochrome c bound to the phosphoprotein phosvitin

The relationship between the structure and function of ferricytochrome c bound to the phosphoprotein phosvitin was investigated. The rates of reduction of phosvitin-bound ferricytochrome c by cytochrome b2, ascorbate and the superoxide radical generated by xanthine oxidase wer repressed where the binding ratio was less than half the maximum, but at higher ratios they were restored gradually with increase in the ratio. The affinity of cytochrome b2 for cytochrome c was not affected by binding of cytochrome c to phosvitin. The redox potential of the bond form was lower than that of the free form and only decreased with decrease in the ratio. The conformatin around the heme moiety and the electronic structure of the heme group of bound ferricytochrome c were similar to those of free ferricytochrome c, but the conformational stability in the vicinity of the prosthetic group was related to the binding ratio as ratios above half the maximum and was well correlated with the reduction rate. Since the binding of cytochrome c to phosvitin is much stronger at binding ratios below half the maximum, these results suggest that this binding strength exclusively affects the conformational flexibility of the heme crevice in the cytochrome molecule, thus altering the reduction rate.     

Atomic coordinates for ferricytochrome c2 of Rhodospirillum rubrum

Atomic coordinates and backbone torsion angles are tabulated for ferricytochrome $\text{c}{}_2$ of $\text{Rhodospirillum rubrum}$.     

Microcalorimetric studies of conformational transitions of ferricytochrome c in acidic solution

The conformational transitions of ferricytochrome c in acidic solutions with different NaCl concentrations have been studied by scanning and isothermal microcalorimetry. It is shown that ferricytochrome c adopts three different forms which are realized under the considered conditions: native, denatured (unfolded) and a compact native-like form with unique tertiary structure. The thermodynamic parameters of the corresponding transitions have been measured and the changes in the number of bound ligands (H+ and Cl-), accompanying these transitions, have been determined by analyzing the temperature, pH and ionic strength dependence of these parameters.     

Interaction of ferricytochrome c with liposomes

The binding of ferricytochrome c to liposomes consisting of phosphatidylcholine mixtures with cardiolipin (3:1) or phosphatidylserine (3:1) has been investigated. Experimental data have been analyzed in terms of two-dimensional models of large ligand adsorption. The equilibrium parameters of ferricytochrome c interaction with a phospholipid bilayer are determined.     

pH-dependent conformational changes of ferricytochrome c induced by electrode surface microstructure

pH-dependent processes of bovine heart ferricytochrome c have been investigated by electronic absorption and circular dichroism (CD) spectra at functionalized single-wall carbon nanotubes (SWNTs) modified glass carbon electrode (SWNTs/GCE) using a long optical path thin layer cell. These methods enabled the pH-dependent conformational changes arising from the heme structure change to be monitored. The spectra obtained at functionalized SWNTs/GCE reflect electrode surface microstructure-dependent changes for pH-induced protein conformation, pK_a of alkaline transition and structural microenvironment of the ferricytochrome c heme. pH-dependent conformational distribution curves of ferricytochrome c obtained by analysis of in situ CD spectra using singular value decomposition least square (SVDLS) method show that the functionalized SWNTs can retain native conformational stability of ferricytochrome c during alkaline transition.     

Alkaline isomerization of ferricytochrome C from Euglena gracilis

$\text{Euglena gracilis}$ ferricytochrome $\text{c}$ has a small absorption maximum at about 700 nm having an extinction of 850 ± 10 M^?1cm^?1. This absorption band is analogous to the more commonly found maximum at 695 nm which is observed in ferricytochromes from other sources and which is characteristic of ligation of methionine 80 with the heme ion. The 700 nm band disappears upon raising the pH to 11 giving a transition involving a single proton having an apparent pK of about 10. These results demonstrate that the phenolic ionization of tyrosine 67 is not required to trigger the alkaline isomerization of ferricytochromes $\text{c}$ since Euglena cytochrome has a phenylalanine residue at position 67.     

Cytochrome c and cytochrome c peroxidase complex as studied by resonance Raman spectroscopy.

Complex formation between ferricytochrome c peroxidase (CCP) and ferricytochrome c from yeast [cyt(Y)] and horse heart [cyt(H)] was studied by resonance Raman spectroscopy. On the basis of a detailed spectral analysis of the free proteins, it was possible to attribute changes in the spectra of the complexes to the individual proteins. At pH 7.0 both cyt(Y) and cyt(H) binding induces an increase in the six-coordinate low-spin configuration of CCP from 9% to 19% at the expense of the five-coordinate high-spin state, which drops from 84% to 74%. In the free and complexed state, CCP exhibits a constant fraction of the six-coordinate high-spin form (approximately 7%). In addition to affecting the coordination state, there is also a cyt-specific structural response of CCP to complexation. In the cyt(Y)-CCP complex, the peripheral vinyl and propionate substituents of CCP are more rigidly fixed in the protein matrix, whereas binding of cyt(H) only slightly perturbs the conformations of these side chains. The biological significance of the conformational changes in CCP are discussed. In contrast to CCP, there are no detectable structural changes in either cyt(Y) or cyt(H) upon complex formation.     

One-electron reactions in biochemical systems as studied by pulse radiolysis. VI. Stages in the reduction of ferricytochrome c

When ferricytochrome c at pH about 9 is reduced by hydrated electrons and/or CO₂^?, it gives rise to an unstable form of ferrocytochrome c whose absorption spectrum, particularly in the Soret region, differs from that of normal ferrocytochrome c. This form changes intramolecularly (life-time about 0.1 s at ambient temperature) to yield normal ferrocytochrome c, and by 0.5 s the change in absorption spectrum in the range 225–600 nm produced by e^?_aq and/or CO₂^? is identical to the final change produced by reduction with an equivalent amount of sodium dithionite. This shows that both e^?_aq and CO^?₂ reduce cytochrome c with practically 100% efficiency. In the range 600–800 nm the spectrum of the unstable form is the same as that of normal ferrocytochrome c, both having small absorptions at 695 nm as compared with ferricytochrome c. As the unstable form disappears however a further loss of absorption at 695 nm occurs. This is taken to imply that the unstable form decays to a second unstable form which then rapidly donates an electron to the unchanged neutral form of ferricytochrome c, so reducing absorption in the 695 nm band. Subsequent to this process the absorption in the 695 nm band increases over a period of minutes owing to re-equilibration between the neutral and alkaline formes of ferricytochrome c. Between pH 7 and 10 the effect of pH on the absorption changes is consistent with the hypothesis of a second unstable form of ferrocytochrome c. Additional phenomena arise in more alkaline solutions. The rates of the various unimolecular processes are thought to be determined by the rates of change of conformation of the protein parts of the molecule following the change in oxidation state.     

Hydrogen ion titration of horse heart ferricytochrome c.

Continuous hydrogen ion titration curves of deionized solutions of horse heart ferricytochrome c have been obtained at 25 degrees C. at a constant ionic strength of 0.10 from pH 3.0 to 11.0. Titration of the oxidized protein in KCl required 28.4 equiv over that pH range, and a small hysteresis between the forward and reverse limbs was displayed. The Linderstrom-Lang approximation, which takes into account electrostatic interactions between charged groups on the protein surface, was used in a computer simulation program to analyze the forward and reverse limbs of the titration curve separately. The results indicated 1 alpha-, 12 beta- and gamma-, and 1 heme propionic carboxylic, 1 imidazole, 1 phenolic, and 18 epsilon-amino residues appear to titrate normally. Variations in the electrostatic interaction factor omega suggest conformational changes in the protein at the extremes of pH, although the relationship of the variations in omega to the magnitude of the conformational changes does not appear to be strictly quantitative for cytochrome c. These results show the acid-base behavior of cytochrome c to be complex in nature, and suggest that the Lindenstrom-Lang model may not be adequate for cytochrome c.     

Hydration-State Change of Horse Heart Cytochrome c Corresponding to Trifluoroacetic-Acid-Induced Unfolding

We investigate the hydration state of horse-heart cytochrome c (hh cyt c) in the unfolding process induced by trifluoroacetic acid (TFA). The conformation of hh cyt c changes from the native (N) state (2.9 < pH < 6.0) to the acid-unfolded (U_A) state (1.7 < pH < 2.0) to the acid-induced molten globule (A) state (pH ∼1.2). Hydration properties of hh cyt c during this process are measured at 20°C by high-resolution dielectric relaxation (DR) spectroscopy, UV-vis absorbance, and circular dichroism spectroscopy. Constrained water of hh cyt c is observed at every pH as an ∼5-GHz Debye component (DC) (DR time, τ_D ∼30 ps) and its DR amplitude (DRA) is increased by 77% upon N-to-U_A transition, when pH changes from 6.0 to 2.0. Even in the N state, the DRA of the constrained-water component is found to be increased by 22% with decreasing pH from 6.0 to 2.9, suggesting an increase in the accessible surface area of native hh cyt c. Moreover, hypermobile water around native hh cyt c is detected at pH 6.0 as a 19-GHz DC (τ_D ∼ 8.4 ps < τ_DW = 9.4 ps), but is not found at other pH values. The DRA signal of constrained water is found to return to the pH 2.9 (N-state) level upon U_A-to-A transition. Fast-response water (slightly slower than bulk) around A-state hh cyt c is detected at pH 1.2, and this suggests some accumulation of TFA⁻ ions around the peptide chain. Thus, this high-resolution DR spectroscopy study reveals that hh cyt c exhibits significant hydration-state change in the TFA-unfolding process.     

Kinetics and mechanism of the reduction of horse heart ferricytochrome c by glutathione.

A detailed investigation of the reduction of cytochrome c by glutathione has shown that the reaction proceeds through several steps. A rapid combination of the reducing agent with the cytochrome leads to the formation of a glutathione-cytochrome intermediate in which the glutathione most likely interacts with the edge of the heme moiety. The electron transfer takes place in a subsequent slower step. Since cytochrome c(III) exists in two conformational forms at neutral pH [Kujundzic, N., & Everse, J. (1978) Biochem. Biophys. Res. Commun. 82, 1211], the reduction of cytochrome c by glutathione may be represented by cyt c(III) + GS- reversible K1 cyt c(III) ... GS- reversible k1 products cyt c*(III) + GS- reversible K2 cyt c*(III) ... GS- reversible k2 products At 25 degrees C, pH 7.5, and an ionic strength of 1.0 (NaCl), k1 = 1.2 X 10(-3) S-1, k2 = 2.0 X 10(-3) S-1, k1 = 2.9 X 10(3) M-1, and K2 = 5.3 X 10(3) M-1. The reaction is catalyzed by trisulfides, and second-order rate constants of 4.55 X 10(3) and 7.14 X 10(3) M-1 S-1 were obtained for methyl trisulfide and cysteine trisulfide, respectively.     

Effect of varying polyglutamate chain length on the structure and stability of ferricytochrome c

The effect of varying polyglutamate chain length on local and global stability of horse heart ferricytochrome c was studied using scanning calorimetry and spectroscopy methods. Spectral data indicate that polyglutamate chain lengths equal or greater than eight monomer units significantly change the apparent pK(a) for the alkaline transition of cytochrome c. The change in pK(a) is comparable to the value when cytochrome c is complexed with cytochrome bc(1). Glutamate and diglutamate do not significantly alter the temperature transition for cleavage of the Met(80)-heme iron bond of cytochrome c. At low ionic strength, polyglutamates consisting of eight or more glutamate monomers increase midpoint of the temperature transition from 57.3+/-0.2 to 66.9+/-0.2 degrees C. On the other hand, the denaturation temperature of cytochrome c decreases from 85.2+/-0.2 to 68.8+/-0.2 degrees C in the presence of polyglutamates with number of glutamate monomers n >or approximately equal 8. The rate constant for cyanide binding to the heme iron of cytochrome c of cytochrome c-polyglutamate complex also decreases by approximately 42.5% with n>or approximately equal 8. The binding constant for the binding of octaglutamate (m.w. approximately 1000) to cyt c was found to be 1.15 x 10(5) M(-1) at pH 8.0 and low ionic strength. The results indicate that the polyglutamate (n>or approximately equal 8) is able to increase the stability of the methionine sulfur-heme iron bond of cytochrome c in spite of structural differences that weaken the overall stability of the cyt c at neutral and slightly alkaline pH.     

Selective Cytochrome c Displacement by Phosphate and Ca2+ in Brain Mitochondria

In brain mitochondria, phosphate- and Ca²⁺-dependent cytocrome c (cyt c) release reveals pools that interact differently with the inner membrane. Detachment of the phosphate-dependent pool did not influence the pool released by Ca²⁺. Cyt c pools were also detected in a system of cyt c reconstituted in cardiolipin (CL) liposomes. Gradual binding of cyt c (1 nmol) to CL/2–[12-(7-nitrobenz- 2-oxa-1,3-diazol-4-yl)amino]dodecanoyl-1-hexadecan oyl-sn-glycero-3-phosphocholine (NBDC₁₂-HPC) liposomes (10 nmol) produced NBD fluorescence quenching up to 0.4 nmol of added protein. Additional bound cyt c did not produce quenching, suggesting that cyt c-CL interactions originate distinct cyt c pools. Cyt c was removed from CL/NBDC₁₂-HPC liposomes by either phosphate or Ca²⁺, but only Ca²⁺ produced fluorescence dequenching and leakage of encapsulated 8-aminonaphthalene-1,3,6-trisulfonic acid/p-xylene-bis-pyridinium bromide. In mitochondria, complex IV activity and mitochondrial membrane potential (Δψ_m) were not affected by the release of the phosphate-dependent cyt c pool. Conversely, removal of cyt c by Ca²⁺ caused inhibition of complex IV activity and impairment of Δψ_m. In a reconstituted system of mitochondria, nuclei and supernatant, cyt c detached from the inner membrane was released outside mitochondria and triggered events leading to DNA fragmentation. These events were prevented by enriching mitochondria with exogenous CL or by sequestering released cyt c with anti-cyt c antibody.     

Cytochrome c forms complexes and is partly reduced at interaction with GPI-anchored alkaline phosphatase

Cytochrome (cyt) c forms complexes, undergoes a conformational change and becomes partly reduced at interaction with membrane anchored alkaline phosphatase (AP), a glycoprotein which is released into the body fluid in forms differing in hydrophobicity. The proportion of products formed in the mixtures depends on pH, ionic strength, temperature and the buffer composition. The reaction terminates in an equilibrium between cyt c(FeII) and other cyt c conformers. Optimal conditions for the rate of the reaction are 100 mM glycine/NaOH, pH 9.7–9.9, at which 68–74% of cyt c is found in the reduced state. The interaction affects compactness of the haem cleft as shown by changes induced in CD spectra of the Soret region and changes in optical characteristics of phenylalanine, tyrosine and tryptophan residues. Differential scanning calorimetry of AP+cyt c mixtures revealed a creation of at least two types of complexes. A complex formed by non-coulombic binding prevails at substoichiometric AP/cyt c ratios, at higher ratios more electrostatic attraction is involved and at 1:1 molar ratio an apparent complexity of binding forces occurs. The rapid phase of the cyt c(FeII) formation depends on the presence of the hydrophobic alkylacylphosphoinositol (glycosylphosphatidylinositol) moiety, the protein part of the enzyme participates in an electrostatic and much slower phase of cyt c(FeII) creation. The results show that non-coulombic interaction may participate at interaction of cyt c with cellular proteins.     

Subtle Change in the Charge Distribution of Surface Residues May Affect the Secondary Functions of Cytochrome c

Although the primary function of cytochrome c (cyt c) is electron transfer, the protein caries out an additional secondary function involving its interaction with membrane cardiolipin (CDL), its peroxidase activity, and the initiation of apoptosis. Whereas the primary function of cyt c is essentially conserved, its secondary function varies depending on the source of the protein. We report here a detailed experimental and computational study, which aims to understand, at the molecular level, the difference in the secondary functions of cyt c obtained from horse heart (mammalian) and Saccharomyces cerevisiae (yeast). The conformational landscape of cyt c has been found to be heterogeneous, consisting of an equilibrium between the compact and extended conformers as well as the oligomeric species. Because the determination of relative populations of these conformers is difficult to obtain by ensemble measurements, we used fluorescence correlation spectroscopy (FCS), a method that offers single-molecule resolution. The population of different species is found to depend on multiple factors, including the protein source, the presence of CDL and urea, and their concentrations. The complex interplay between the conformational distribution and oligomerization plays a crucial role in the variation of the pre-apoptotic regulation of cyt c observed from different sources. Finally, computational studies reveal that the variation in the charge distribution at the surface and the charge reversal sites may be the key determinant of the conformational stability of cyt c.