Order parameters and orientation distributions of solution adsorbed and microcontact printed cytochrome c protein films on glass and ITO

The structure of solution adsorbed and microcontact printed (muCP) cytochrome c (cyt c) films on glass and indium tin oxide (ITO) was investigated using attenuated total reflectance (ATR) and total internal reflectance fluorescence (TIRF) spectroscopies to determine the orientation of the heme groups in the films. The second and fourth order parameters of the heme as well as information on the angle between the absorption and emission dipoles of the heme, gamma, were experimentally determined. The order parameters of the heme are related to the order parameters of the protein molecule using the known angle between the heme plane and the electrostatic dipole moment of the cyt c protein. The effect of the surface roughness of the substrates (glass and ITO) was also taken into account quantitatively using AFM data. Physically possible order parameters were obtained for the heme group in both solution adsorbed and muCP films, but not for the electrostatic dipole moment of the protein. In addition, the experimental values of {cos2 gamma} for immobilized zinc-substituted cyt c are greater than the values of {cos2 gamma} determined in viscous solutions, which could be an indication that the environment of the heme groups changes upon adsorption. The electron transfer behavior of solution adsorbed and muCP films on ITO, determined using electrochemical methods, is compared to their orientation distribution and surface coverage as determined by spectroscopic methods.     

pH-Dependent peroxidase activity of yeast cytochrome c and its triple mutant adsorbed on kaolinite

The peroxidase activity of wild-type yeast cytochrome c and its triple mutant K72AK73AK79A adsorbed onto kaolinite was investigated as a function of pH and temperature. Both adsorbed proteins displayed an appreciable catalytic activity, which remained constant from pH 7 to pH 10, decreased below pH 7, and showed a remarkable increase at pH values lower than 4. In the whole pH range investigated the catalytic activity of the adsorbed wild-type cytochrome c was higher than that of the mutant. Both diffuse-reflectance UV-vis and resonance Raman spectroscopies applied on solid samples were used to probe the structural features responsible for the catalytic activity of the immobilized proteins. At neutral and alkaline pH values a six-coordinate low-spin form of cytochrome c was observed, while at pH < 7 the formation of a high-spin species occurred whose population increased at decreasing pH. The orientation and exposure of the heme to the substrate-strictly dependent on adsorption-was found to affect the peroxidase activity.     

Structures of Cytochrome b_5 Mutated at the Charged Surface-Residues and Their Interactions with Cytochrome c

ＩｎｔｒｏｄｕｃｔｉｏｎＭｉｃｒｏｓｏｍａｌｃｙｔｏｃｈｒｏｍｅｂ5(Ｃｙｔｂ5)ｉｓａｍｅｍｂｅｒｏｆｃｙｔｏｃｈｒｏｍｅｂ5ｆａｍｉｌｙ ,ａｎｄｉｔｓｅｒｖｅｓａｓａｎｅｌｅｃｔｒｏｎｃａｒｒｉｅｒｉｎａｓｅｒｉｅｓｏｆｅｌｅｃｔｒｏｎ ｔｒａｎｓｆｅｒｐｒｏｃｅｓｓｅｓｉｎｂｉｏｌｏｇｉｃａｌｓｙｓ ｔｅｍｓ .1 3 Ｃｙｔｂ5ｉｓａｍｅｍｂｒａｎｅｐｒｏｔｅｉｎｗｉｔｈＭｒ～ 16ｋＤａ ,ｃｏｎｓｉｓｔｉｎｇｏｆｔｗｏｄｏｍａｉｎｓ ,ｏｎｅｈｙｄｒｏｐｈｏｂｉｃｄｏｍａｉｎｗｈｉｃｈａｎｃｈｏｒｓｔｈ…     

纳米金三明治结构调制细胞色素c电子传递特性的分子机理研究

以细胞色素c(Cyt c)为模型蛋白,采用表面增强红外吸收光谱监测了三明治结构所吸附的纳米金对氧化还原诱导的Cyt c表面增强红外差谱的改变.研究表明,在单层Cyt c分子表面组装纳米金,使得血红素的红外差谱特征峰明显增强,这归因于纳米金和血红素之间的电子传递.纳米金与Cyt c氧化还原活性中心血红素的相互作用加速了蛋白质的电子传递.这为实现并优化表面吸附蛋白质的直接电化学提供了一种新技术.     

Direct wiring of cytochrome c's heme unit to an electrode: electrochemical studies

A novel strategy for the immobilization of cytochrome c on the surface of chemically modified electrodes is demonstrated and used to investigate the protein's electron-transfer kinetics. Mixed monolayer films of alkanethiols and omega-terminated alkanethiols (terminated with pyridine, imidazole, or nitrile groups that are able to ligate with the heme) are used to adsorb cytochrome c to the surface of gold electrodes. The use of mixed films, as opposed to pure films, allows the concentration of adsorbed cytochrome to remain dilute and ensures a higher degree of homogeneity in their environment. The adsorbed protein is studied using electrochemical methods and scanning tunneling microscopy.     

Dissociation reactions of gaseous ferro-, ferri-, and apo-cytochrome c ions

Electrochemical reduction of the iron bound in the heme group of cytochrome c is shown to occur in the nano-electrospray capillary if the protein is sprayed from neutral water using a steel wire as the electrical contact. Quadrupole ion trap collisional activation is used to study the dissociation reactions of cytochrome c as a function of the oxidation state of the iron. Oxidized (Fe(III)) cytochrome c dissociates via sequence-specific amide bond cleavage, while the reduced (Fe(II)) form of the protein dissociates almost exclusively by loss of protonated heme. Apo-cytochrome c, from which the heme has been removed either via gas-phase dissociation of the reduced holo-protein or via solution chemistry, dissociates via amide bond cleavage in similar fashion to the oxidized holo-protein.     

Effects of mutational (Lys to Ala) surface charge changes on the redox properties of electrode-immobilized cytochrome c

Untrimethylated yeast iso-1-cytochrome c (cytc) and its single and multiple Lys to Ala variants at the surface lysines 72, 73, and 79 were adsorbed on carboxyalkanethiol self-assembled monolayers (SAMs) on gold, and the thermodynamics and kinetics of the heterogeneous protein-electrode electron-transfer (ET) reaction were determined by voltammetry. The reaction thermodynamics were also measured for the same species freely diffusing in solution. The selected lysine residues surround the heme group and contribute to the positively charged domain of cytc involved in the binding to redox partners and to carboxyl-terminated SAM-coated surfaces. The E degrees' (standard reduction potential) values for the proteins immobilized on SAMs made of 11-mercapto-1-undecanoic acid and 11-mercapto-1-undecanol on gold were found to be lower than those for the corresponding diffusing species owing to the stabilization of the ferric state by the negatively charged SAM. For the immobilized proteins, Lys to Ala substitution(s) do not affect the surface coverage, but induce significant changes in the E degrees' values, which do not simply follow the Coulomb law. The results suggest that the species-dependent orientation of the protein (and thereby of the heme group) toward the negatively charged SAM influences the electrostatic interaction and the resulting E degree' change. Moreover, these charge suppressions moderately affect the kinetics of the heterogeneous ET acting on the reorganization energy and the donor-acceptor distance. The kinetic data suggest that none of the studied lysines belong to the interfacial ET pathway.     

细胞色素c在经预处理的金电极上电化学行为的研究

本文观察到吸附态和本体态的细胞色素ｃ以经预处理的金电极上的准可逆反应。采用现场ＦＴＩＲ光谱法，紫外可见反射光谱法，循环伏安法，交流阻抗法和电位阶跃法研究了细胞色素ｃ吸附行为和反应动力学。     

A Colloidal Au Monolayer Modulates the Conformation and Orientation of a Protein at the Electrode/Solution Interface

The orientation and conformation of adsorbed cytochrome c (cyt c) at the interface between an electrode modified with colloidal Au and a solution were studied by electrochemical, spectroscopic, and spectroelectrochemical techniques. The results indicate that the colloidal Au monolayer formed via preformation of an organic self‐assembled monolayer (SAM) can increase the electronic coupling between the SAM and cyt c in the same manner as bifunctional molecular bridges, one functional group of which is bound to the electrode surface while the other interacts with the protein surface. The approach of cyt c to the modified electrode/solution interface can be assisted by strong interactions of the intrinsic charge of colloidal particles with cyt c, while the heme pocket remains almost unchanged due to the screening effect of the negatively charged field created by the intrinsic charge. The conformational changes of cyt c induced by its adsorption at a bare glassy carbon electrode/solution interface and the effect of the electric field on the ligation state of the heme can be avoided at the colloidal‐Au‐modified electrode/solution interface. Finally, a possible model for the adsorption orientation of cyt c at the colloidal‐Au‐modified electrode/solution interface is proposed.     

Acid Denaturation and Refolding of Cytochrome c on Silica Surface

Denaturation of oxidized cytochrome c (cyt c) adsorbed to a hydrophilic fused silica surface was studied by UV‐VIS attenuated total reflection (ATR) spectroscopy using a multiple optical pass system newly developed by this lab. Cyt c surface adsorption at neutral pH gave an adsorption equilibrium constant of K_a = 2 × 10⁵ M^?1 and a surface coverage at 63% of a monolayer saturation. Protein unfolding by acid denaturation was studied by equilibrating surface bound cyt c with acid buffers ranging in pH from 5 to 2. Protein orientation and surface coverage were calculated based on a theoretical model developed in previous work. The average heme tilt angle (44°) was found to be independent of pH, implicating protein‐surface interactions as the dominant factor governing adsorption. A non‐random molecular orientation distribution of cyt c on the surface was observed, providing further support for the dominance of protein‐surface interactions. It was shown that when denaturing acid buffers were removed and replaced with a neutral buffer cyt c refolded, assuming their original conformation. The combination of unique, yet applicable, science and laboratory skills involved in this project had a tremendous impact on the authors‘ undergraduate curriculum, making it ideal for capstone project development.     

Redox reaction of PEO modified cytochrome c adsorbed on the electrode in ion conductive PEO matrix analyzed with non-contact optical waveguide spectroscopy

Optical waveguide spectroscopy was used under non-contact conditions to analyze the visible absorption spectrum of poly(ethylene oxide) (M _w = 150) modified cytochrome c (PEO₁₅₀-cyt.c) adsorbed on an indium tin oxide (ITO) glass electrode. The redox reactions of the adsorbed PEO₁₅₀-cyt.c were dynamically measured in situ in PEO oligomers (M _w = 200). It was confirmed that PEO modification of cyt.c is effective in maintaining the redox activity of the cyt.c after adsorption on the ITO glass electrode. The PEO₁₅₀-cyt.c adsorbed on the electrode re-dissolved gradually in PEO oligomer. Against this, PEO₁₀₀₀-cyt.c having longer PEO chains (M _w = 1000) was found to be adsorbed stably on the electrode. Copyright © 2003 John Wiley & Sons, Ltd.     

吸附色素蛋白与纳米银粒子间的光诱导电子传递

采用表面增强拉曼光谱研究了吸附态微过氧化物酶和细胞色素c的光诱导还原.结果表明,吸附于粗糙银电极表面的过氧化物酶和细胞色素c在413nm激光连续照射下被部分还原.光诱导还原可归因于电极表面纳米银粒子的定域表面等离子体吸收使得自由电子受激,受激电子进而转移进入吸附分子空轨道,导致吸附蛋白质的还原.     

Effect of mono-CDNP substitution of lysine residues on the redox reaction of cytochrome c electrostatically adsorbed on a mercaptoheptanoic acid modified Au(111) surface

The effect of charge-inverting modification of single surface lysine residue on the electron transfer (ET) reaction of horse heart cytochrome c (cyt c) is examined for 12 different types of mono-4-chloro-2,5-dinitrobenzoic acid substituted cyt c (mCDNPc) adsorbed on a Au(111) electrode modified with a self-assembled monolayer (SAM) of 7-mercapto-heptanoic acid (MHA). A negative shift in the redox potential by 10-35 mV as compared to that of native cyt c and a monolayer coverage in the range of 13-17 pmol cm(-2) are observed for electroactive mCDNPc's. The magnitude of the decrease in the ET rate constant (k(et)) of mCDNPc's compared with that of native cyt c depends on the position of the CDNP substitution. For mCDNPc's in which the modified lysine residue is outside of the interaction domain of cyt c with the SAM, the ratio of the k(et) of mCDNPc to that of native cyt c is correlated to the change in the dipole moment vector of cyt c due to the CDNP modification. This correlation suggests that the dipole moment of cyt c determines its orientation of adsorption on the SAM of MHA and significantly affects the rate of the ET. The CDNP modification of lysine residues at the interaction domain significantly decreases the rate, demonstrating the importance of the local charge environment in determining the rate of ET.     

Clarification of a peak at m/z 1634 from tryptically digested cytochrome c

A peptide peak at m/z 1634 in the mass spectrum of tryptically digested cytochrome c has been ambiguously assigned to either a peptide IFVQKCAQCHTVEK or a peptide CAQCHTVEK combined with a heme group (CAQCHTVEK + heme (Fe(III))). A comprehensive investigation was performed to clearly identify the origin of the peak. Tryptic digests of cytochrome c were analyzed by matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry (MALDI‐TOF MS), liquid chromatography‐tandem MS (LC‐MS/MS), LC‐ultraviolet (LC‐UV), and MALDI Fourier transform‐ion cyclotron resonance (FT‐ICR) MS. The use of instruments with extremely high mass accuracy revealed the mass difference between the IFVQKCAQCHTVEK and the (CAQCHTVEK + heme (Fe(III))) ions. Fragmentation of the peptide associated with the unknown peak yielded a heme ion and other fragment ions originating from a (CAQCHTVEK + heme (Fe(III))) ion. Furthermore, an absorption peak at 395 nm confirmed the presence of a heme group in the unknown peptide. High mass accuracy analyses of MS and MS/MS spectra, in addition to three‐dimensional UV contour mapping, showed that the peak at m/z 1634 is due to a (CAQCHTVEK + heme (Fe(III))) ion and not from protonated IFVQKCAQCHTVEK. Copyright © 2012 John Wiley & Sons, Ltd.     

Electron-transfer pathways between redox enzymes and electrode surfaces: reagentless biosensors based on thiol-monolayer-bound and polypyrrole-entrapped enzymes

Based on previous results which showed that quinohemo-protein alcohol dehydrogenase (QH-ADH) entrapped within polypyrrole is able to directly transfer electrons via the conducting polymer to the electrode surface, the electron-transfer properties of this multi-cofactor enzyme adsorbed and covalently-bound to self-assembled thiol monolayers and bare electrode surfaces has been investigated more closely. While the dissolved enzyme is able to transfer electrons to the electrode via heme c as well as via the more deeply buried PQQ (fast adsorption-chemical reaction-desorption mechanism), an orientation of adsorbed QH-ADH on hydrophobic electrode surfaces, as well as of adsorbed and covalently bound QH-ADH on negatively-charged thiol monolayers could be observed. In these cases the heme c units are pointing towards the electrode surfaces resulting in an optimised direct ET rate.     

Heme axial methionine fluxion in Pseudomonas aeruginosa Asn64Gln cytochrome c551

Heme axial methionine ligands in ferricytochromes c552 from Hydrogenobacter thermophilus (HT) and Nitrosomonas europaea, both members of the cyt c8 family, display fluxional behavior. The ligand motion, proposed to be inversion at sulfur, results in an unusually small range of hyperfine shifts for heme substituents in these proteins. Herein, heme axial Met fluxion is induced in a structurally homologous cytochrome c551 from Pseudomonas aeruginosa (PA) by substituting heme pocket residue Asn64 with Gln. The mutant, PA-N64Q, displays a highly compressed range of heme substituent hyperfine shifts, temperature-dependent heme methyl resonance line broadening, low rhombic magnetic anisotropy, and a magnetic axes orientation consistent with Met orientational averaging. Analysis of NMR properties of PA-N64Q demonstrates that the heme pocket of the mutant resembles that of HT. This result confirms the importance of peripheral interactions and, in particular, residue 64 in determining axial Met orientation and heme electronic structure in proteins in the cyt c8 family.     

Modeling and computations of the intramolecular electron transfer process in the two-heme protein cytochrome c(4)

The di-heme protein Pseudomonas stutzeri cytochrome c(4) (cyt c(4)) has emerged as a useful model for studying long-range protein electron transfer (ET). Recent experimental observations have shown a dramatically different pattern of intramolecular ET between the two heme groups in different local environments. Intramolecular ET in homogeneous solution is too slow (>10 s) to be detected but fast (ms-μs) intramolecular ET in an electrochemical environment has recently been achieved by controlling the molecular orientation of the protein assembled on a gold electrode surface. In this work we have performed computational modeling of the intramolecular ET process by a combination of density functional theory (DFT) and quantum mechanical charge transfer theory to disclose reasons for this difference. We first address the electronic structures of the model heme core with histidine and methionine axial ligands in both low- and high-spin states by structure-optimized DFT. The computations enable estimating the intramolecular reorganization energy of the ET process for different combinations of low- and high-spin heme couples. Environmental reorganization free energies, work terms ("gating") and driving force were determined using dielectric continuum models. We then calculated the electronic transmission coefficient of the intramolecular ET rate using perturbation theory combined with the electronic wave functions determined by the DFT calculations for different heme group orientations and Fe-Fe separations. The reactivity of low- and high-spin heme groups was notably different. The ET rate is exceedingly low for the crystallographic equilibrium orientation but increases by several orders of magnitude for thermally accessible non-equilibrium configurations. Deprotonation of the propionate carboxyl group was also found to enhance the ET rate significantly. The results are discussed in relation to the observed surface immobilization effect and support the notion of conformationally gated ET.     

Reversible Electrochemistry of Cytochrome c on Recompressed,Binderless Exfoliated Graphite Electrodes

The direct electrochemistry of cytochrome c (cyt‐c) has been investigated on exfoliated graphite (EG) electrodes. The as‐polished and roughened (using SiC emery sheet) EG surfaces are inactive for the direct electron transfer. However, when the EG electrode was sonicated before the experiment, a pair of redox waves were obtained for freely diffusing cyt‐c in the solution phase. The formal potential was found to be 0.01 V (vs. SCE) in 0.1 M phosphate buffer at a pH of 7.1. The electrochemical response for the adsorbed cyt‐c on sonicated EG electrodes, which is shown to have carbonyl functional groups on its surface, shows nearly reversible voltammograms in the same electrolyte. However, the formal potential in the adsorbed state is more negative than that observed for the solution phase cyt‐c. A structure based on an open heme conformation proposed by Hildebrandt and Stockburger is probably present on the EG surface. It is suggested that the electrochemistry at the EG electrode is essentially governed by favourable electrostatic interactions.     

Modification of <Emphasis Type="Italic">Cytochrome c</Emphasis> by 4-hydroxy- 2-nonenal: Evidence for histidine,lysine, and arginine-aldehyde adducts

4-Hydroxy-2-nonenal (4HNE), a major secondary product of lipid peroxidation, has been associated with a number of disease states involving oxidative stress. Despite the recognized importance of post-translational modification of proteins by products such as 4HNE, little is known of the modification of cytochrome c by this reagent and its analysis by mass spectrometry. The purpose of this study was to investigate the chemical interaction of 4HNE and cytochrome c, a protein essential to cellular respiration, under in vitro conditions. Isoelectric focusing of native and 4HNE-modified cytochrome c using immobilized pH gradient (IpG) strips showed a decrease in the pI of the 4HNE-modified protein suggesting modification of charged amino acids. Reaction of 4HNE with cytochrome c resulted in increases in molecular weight consistent with the addition of four 4HNE residues as determined by matrix-assisted laser desorption time-of-flight mass spectrometry (MALDI-TOF MS). Samples of both native and 4HNE-modified cytochrome c were enzymatically digested and subjected to peptide mass fingerprinting using MALDI-TOF MS. Analysis of these samples using LC-electrospray ionization tandem mass spectrometry (LC-ESI-MS/MS) provided sequence information that was used to determine specific residues to which the aldehyde adducted. Taken together, the data indicated that H33, K87, and R38 were modified by 4HNE. Mapping these results onto the X-ray crystal structure of native cytochrome c suggest that 4HNE adduction to cytochrome c could have significant effects on tertiary structure, electron transport, and ultimately, mitochondrial dysfunction.     

De novo design of a D2-symmetrical protein that reproduces the diheme four-helix bundle in cytochrome bc1

An idealized, water-soluble D(2)-symmetric diheme protein is constructed based on a mathematical parametrization of the backbone coordinates of the transmembrane diheme four-helix bundle in cytochrome bc(1). Each heme is coordinated by two His residues from diagonally apposed helices. In the model, the imidazole rings of the His ligands are held in a somewhat unusual perpendicular orientation as found in cytochrome bc(1), which is maintained by a second-shell hydrogen bond to a Thr side chain on a neighboring helix. The resulting peptide is unfolded in the apo state but assembles cooperatively upon binding to heme into a well-folded tetramer. Each tetramer binds two hemes with high affinity at low micromolar concentrations. The equilibrium reduction midpoint potential varies between -76 mV and -124 mV vs SHE in the reducing and oxidizing direction, respectively. The EPR spectrum of the ferric complex indicates the presence of a low-spin species, with a g(max) value of 3.35 comparable to those obtained for hemes b of cytochrome bc(1) (3.79 and 3.44). This provides strong support for the designed perpendicular orientation of the imidazole ligands. Moreover, NMR spectra show that the protein exists in solution in a unique conformation and is amenable to structural studies. This protein may provide a useful scaffold for determining how second-shell ligands affect the redox potential of the heme cofactor.