Exploring electron transfer between heme proteins of cytochrome C super family in biosensors: a molecular mechanics study

Electron transfer between heme proteins with mediators plays an important role in the fabrication of sensitive bio-nano sensors. Heme protein Cytochrome c (pdb code - 1HRC) was chosen as the mediator with Cytochrome c' (pdb code - 1A7V) as the probe protein for our investigation on the electron transfer process. We used the software GRAMM, HEX, and MACRODOX to build the protein complex with further evaluation by GROMACS potential. After molecular mechanics refinement by GROMACS the protein complexes were evaluated in terms of the following criteria: Hydrophobic packing, proximity of the hemes, hydrogen bonds, enthalpy and entropy of binding. The free energy was calculated for each complex to derive the feasible stable models. The combined electron transport of the chosen geometric models was evaluated to choose the possible models. Electrostatic potential was calculated using the program APBS around the heme in the presence and absence of other proteins. From our studies, we derived multiple feasible models and possible electronic path. These studies helped us to understand the relay mechanism between the two proteins and to design mutant proteins by rational site directed mutagenesis to enhance the redox potential and thereby improving the signal to noise ratio in amperometric bionano sensors.     

Dynamics of electron transfer pathways in cytochrome C oxidase

Cytochrome c oxidase mediates the final step of electron transfer reactions in the respiratory chain, catalyzing the transfer between cytochrome c and the molecular oxygen and concomitantly pumping protons across the inner mitochondrial membrane. We investigate the electron transfer reactions in cytochrome c oxidase, particularly the control of the effective electronic coupling by the nuclear thermal motion. The effective coupling is calculated using the Green's function technique with an extended Huckel level electronic Hamiltonian, combined with all-atom molecular dynamics of the protein in a native (membrane and solvent) environment. The effective coupling between Cu(A) and heme a is found to be dominated by the pathway that starts from His(B204). The coupling between heme a and heme a(3) is dominated by a through-space jump between the two heme rings rather than by covalent pathways. In the both steps, the effective electronic coupling is robust to the thermal nuclear vibrations, thereby providing fast and efficient electron transfer.     

Yeast cytochrome c peroxidase: mechanistic studies via protein engineering

Cytochrome c peroxidase (CcP) is a yeast mitochondrial enzyme that catalyzes the reduction of hydrogen peroxide to water by ferrocytochrome c. It was the first heme enzyme to have its crystallographic structure determined and, as a consequence, has played a pivotal role in developing ideas about structural control of heme protein reactivity. Genetic engineering of the active site of CcP, along with structural, spectroscopic, and kinetic characterization of the mutant proteins has provided considerable insight into the mechanism of hydrogen peroxide activation, oxygen-oxygen bond cleavage, and formation of the higher-oxidation state intermediates in heme enzymes. The catalytic mechanism involves complex formation between cytochrome c and CcP. The cytochrome c/CcP system has been very useful in elucidating the complexities of long-range electron transfer in biological systems, including protein-protein recognition, complex formation, and intracomplex electron transfer processes.     

Active site structure and dynamics of cytochrome c3 from Desulfovibrio gigas immobilized on electrodes

Cytochrome c3 from Desulfovibrio gigas is electrostatically adsorbed on Ag electrodes coated with self-assembled monolayers (SAMs) of 11-mercaptoundecanoic acid. The redox equilibria and electron transfer dynamics of the adsorbed four-heme protein are studied by surface enhanced resonance Raman spectroscopy. Immobilization on the coated electrodes does not cause any structural changes in the redox sites. The potential-dependent stationary experiments distinguish the redox potential of heme IV (-0.19 V versus normal hydrogen electrode) from those of the other hemes for which an average value of -0.3 V is determined. Taking into account the interfacial potential drops, these values are in good agreement with the redox potentials of the protein in solution. The heterogenous electron transfer between the electrode and heme IV of the adsorbed cytochrome c3 is analyzed on the basis of time-resolved experiments, leading to a formal electron transfer rate constant of 15 s(-1), which is a factor of 3 smaller than that of the monoheme protein cytochrome c.     

Structure of cytochrome c6A, a novel dithio-cytochrome of Arabidopsis thaliana, and its reactivity with plastocyanin: implications for function

Cytochrome c6A is a unique dithio-cytochrome present in land plants and some green algae. Its sequence and occurrence in the thylakoid lumen suggest that it is derived from cytochrome c6, which functions in photosynthetic electron transfer between the cytochrome b6f complex and photosystem I. Its known properties, however, and a strong indication that the disulfide group is not purely structural, indicate that it has a different, unidentified function. To help in the elucidation of this function the crystal structure of cytochrome c6A from Arabidopsis thaliana has been determined in the two redox states of the heme group, at resolutions of 1.2 A (ferric) and 1.4 A (ferrous). These two structures were virtually identical, leading to the functionally important conclusion that the heme and disulfide groups do not communicate by conformational change. They also show, however, that electron transfer between the reduced disulfide and the heme is feasible. We therefore suggest that the role of cytochrome c6A is to use its disulfide group to oxidize dithiol/disulfide groups of other proteins of the thylakoid lumen, followed by internal electron transfer from the dithiol to the heme, and re-oxidation of the heme by another thylakoid oxidant. Consistent with this model, we found a rapid electron transfer between ferro-cytochrome c6A and plastocyanin, with a second-order rate constant, k2=1.2 x 10(7) M(-1) s(-1).     

Cytochrome P450 biosensors-a review

Cytochrome P450 (CYP) is a large family of enzymes containing heme as the active site. Since their discovery and the elucidation of their structure, they have attracted the interest of scientist for many years, particularly due to their catalytic abilities. Since the late 1970s attempts have concentrated on the construction and development of electrochemical sensors. Although sensors based on mediated electron transfer have also been constructed, the direct electron transfer approach has attracted most of the interest. This has enabled the investigation of the electrochemical properties of the various isoforms of CYP. Furthermore, CYP utilized to construct biosensors for the determination of substrates important in environmental monitoring, pharmaceutical industry and clinical practice.     

A needle in a haystack: the active site of the membrane-bound complex cytochrome c nitrite reductase

Cytochrome c nitrite reductase is a multicenter enzyme that uses a five-coordinated heme to perform the six-electron reduction of nitrite to ammonium. In the sulfate reducing bacterium Desulfovibrio desulfuricans ATCC 27774, the enzyme is purified as a NrfA2NrfH complex that houses 14 hemes. The number of closely-spaced hemes in this enzyme and the magnetic interactions between them make it very difficult to study the active site by using traditional spectroscopic approaches such as EPR or UV-Vis. Here, we use both catalytic and non-catalytic protein film voltammetry to simply and unambiguously determine the reduction potential of the catalytic heme over a wide range of pH and we demonstrate that proton transfer is coupled to electron transfer at the active site.     

Electron transfer between globular proteins. Dependence of the rate of transfer on distance

Based on the assumption that electron transfer between globular proteins occurs by a collective excitation of polaron type, the dependence of the rate of this process on the distance between the donor and acceptor centers with regard to their detailed electron structure was calculated. The electron structure of the heme was calculated by the quantum-chemical MNDO-PM3 method. The results were compared with experimental data on interprotein and intraglobular electron transfer. It is shown that, in the framework of this model, the electron transfer is not exponential and does not require a particular transfer pathway since the whole protein macromolecule is involved in the formation of the electron excited state.     

Cytochrome bc1 complexes of microorganisms.

The cytochrome bc1 complex is the most widely occurring electron transfer complex capable of energy transduction. Cytochrome bc1 complexes are found in the plasma membranes of phylogenetically diverse photosynthetic and respiring bacteria, and in the inner mitochondrial membrane of all eucaryotic cells. In all of these species the bc1 complex transfers electrons from a low-potential quinol to a higher-potential c-type cytochrome and links this electron transfer to proton translocation. Most bacteria also possess alternative pathways of quinol oxidation capable of circumventing the bc1 complex, but these pathways generally lack the energy-transducing, protontranslocating activity of the bc1 complex. All cytochrome bc1 complexes contain three electron transfer proteins which contain four redox prosthetic groups. These are cytochrome b, which contains two b heme groups that differ in their optical and thermodynamic properties; cytochrome c1, which contains a covalently bound c-type heme; and a 2Fe-2S iron-sulfur protein. The mechanism which links proton translocation to electron transfer through these proteins is the proton motive Q cycle, and this mechanism appears to be universal to all bc1 complexes. Experimentation is currently focused on understanding selected structure-function relationships prerequisite for these redox proteins to participate in the Q-cycle mechanism. The cytochrome bc1 complexes of mitochondria differ from those of bacteria, in that the former contain six to eight supernumerary polypeptides, in addition to the three redox proteins common to bacteria and mitochondria. These extra polypeptides are encoded in the nucleus and do not contain redox prosthetic groups. The functions of the supernumerary polypeptides of the mitochondrial bc1 complexes are generally not known and are being actively explored by genetically manipulating these proteins in Saccharomyces cerevisiae.     

Direct electrochemical analyses of human cytochromes <Emphasis Type="Italic">b</Emphasis><Subscript>5</Subscript> with a mutated heme pocket showed a good correlation between their midpoint and half wave potentials

Background  

Cytochrome b ₅ performs central roles in various biological electron transfer reactions, where difference in the redox potential of two reactant proteins provides the driving force. Redox potentials of cytochromes b ₅ span a very wide range of ~400 mV, in which surface charge and hydrophobicity around the heme moiety are proposed to have crucial roles based on previous site-directed mutagenesis analyses.     

Co-evolution of cytochrome c 6 and plastocyanin, mobile proteins transferring electrons from cytochrome b 6f to photosystem I

 Cytochrome c ₆ and plastocyanin are soluble metalloproteins that act as mobile carriers transferring electrons between the two membrane-embedded photosynthetic complexes cytochrome b ₆ f and photosystem I (PSI). First, an account of recent data on structural and functional features of these two membrane complexes is presented. Afterwards, attention is focused on the mobile heme and copper proteins – and, in particular, on the structural factors that allow recognition and confer molecular specificity and control the rates of electron transfer from and to the membrane complexes. The interesting question of why plastocyanin has been chosen over the ancient heme protein is discussed to place emphasis on the evolutionary aspects. In fact, cytochrome c ₆ and plastocyanin are presented herein as an excellent case study of biological evolution, which is not only convergent (two different structures but the same physiological function), but also parallel (two proteins adapting themselves to vary accordingly to each other within the same organism). Received: 4 July 1996 / Accepted: 16 September 1996     

Soluble cytochromes and a photoactive yellow protein isolated from the moderately halophilic purple phototrophic bacterium, Rhodospirillum salexigens

Three soluble cytochromes were found in two strains of the halophilic non-sulfur purple bacterium Rhodospirillum salexigens. These are cytochromes C2, C and c-551. Cytochrome C2 was recognized by the presence of positive charge at the site of electron transfer (measured by laser flash photolysis), although the protein has an overall negative charge (pI = 4.7). Cytochrome C2 has a high redox potential (300 mV) and is monomeric (13 kDa). Cytochrome c was recognized from its characteristic absorption spectrum. It has a redox potential of 95 mV, an isoelectric point of 4.3, and is isolated as a dimer (33 kDa) of identical subunits (14 kDa), a property which is typical of this family of proteins. R. salexigens cytochrome c-551 has an absorption spectrum similar to the low redox potential Rb. sphaeroides cytochrome c-551.5. It also has a low redox potential (-170 mV), is very acidic (pI = 4.5), and is monomeric (9 kDa), apparently containing 1 heme per protein. The existence of abundant membrane-bound cytochromes c-558 and c-551 which are approximately half reduced by ascorbate and completely reduced by dithionite suggests the presence of a tetraheme reaction center cytochrome in R. salexigens, although reaction centers purified in a previous study (Wacker et al., Biochim. Biophys. Acta (1988) 933, 299-305) did not contain a cytochrome. The most interesting observation is that R. salexigens contains a photoactive yellow protein (PYP), previously observed only in the extremely halophilic purple sulfur bacterium Ectothiorhodospira halophila. The R. salexigens PYP appears to be slightly larger than that of Ec. halophila (16 kDa vs. 14 kDa). Otherwise, these two yellow proteins have similar absorption spectra, chromatographic properties and kinetics of photobleaching and recovery.     

Amelioration of mechanism-based inactivation of CYP3A4 by a H-PGDS inhibitor

This work describes the rational amelioration of mechanism-based inactivation (MBI) of Cytochrome P450 (CYP) 3A4 in a human hematopoietic prostaglandin D synthase (hH-PGDS) inhibitor (cpd 1). We utilized metabolism reports in order to check if patterns in the metabolism of 1 and similar compounds by CYP3A4 could be deciphered. Then we used structure based design, first modifying the CYP3A4 crystal structure (pdb code: 4NY4) by adding an oxyferryl moiety to the heme, followed by validating the modified structure to obtain the 1′ and 4 position oxidation products of midazolam and then recapitulating the metabolism patterns deciphered previously for 1 and analogs. We checked if the pattern deciphered could lead to a putative reactive moiety. Finally we used the docking pose of 1 into this model of the modified CYP3A4 crystal structure to guide transformation of 1 into MBI-free H-PGDS inhibitors.     

An electrochemical investigation of hemoglobin and catalase incorporated in collagen films

Collagen, an electrochemically inert protein, formed films on pyrolytic graphite (PG) electrodes, which provided a suitable microenvironment for heme proteins to transfer electron directly with the underlying electrodes. Hemoglobin (Hb) and catalase (Cat) incorporated in collagen films exhibited a pair of well-defined and quasi-reversible cyclic voltammetric peaks at around -0.35 V and -0.47 V (vs. SCE) in pH 7.0 buffers, respectively, characteristic of the protein heme Fe(III)/Fe(II) redox couples. UV-vis spectra showed that the heme proteins in collagen films retained their near-native conformations in the medium pH range. The results of scanning electron microscopy (SEM) demonstrated that the interaction between heme proteins and collagen made the morphology of dry protein-collagen films different from the collagen films alone. The electrochemical parameters such as apparent heterogeneous electron transfer rate constant (k(s)) and formal potential (E degrees ') of the films were estimated by using square wave voltammograms (SWV) and nonlinear regression analysis. The heme protein-collagen film electrodes were also used to catalyze the reduction of nitrite, oxygen and hydrogen peroxide, indicating potential applications of the films for the fabrication of a new type of biosensor that does not use mediators.     

Heme-thiolate proteins

Cytochrome P450 was the first hemoprotein found to have a thiolate anion as the axial ligand of the heme. Several other heme-thiolate proteins, including nitric oxide synthase, were later found in animals, plants, and microorganisms. Both cytochrome P450 and nitric oxide synthase, two major members of the heme-thiolate protein family, catalyze monooxygenase reactions, but the physiological functions of other heme-thiolate proteins are apparently highly diverse. Chloroperoxidase of a mold, Caldaryomyces fumago, catalyzes a haloperoxidase reaction. CooA of a bacterium, Rhodospirillum rubrum, and heme-regulated eIF2α kinase of animals function as the sensors for carbon monoxide and nitric oxide, respectively, to elicit biological responses to these gases. The role of heme in the enzymatic activity of cystathionine β-synthase is still unknown. It is likely that more heme-thiolate proteins with diversified functions will be found in various organisms in the future.     

Chromatium vinosum cytochrome c-552. Reduction by photoreduced flavins and intramolecular electron transfer

Cytochrome c-552 from Chromatium vinosum is an unusual heme protein in that it contains two hemes and one flavin per molecule. To investigate whether intramolecular electron transfer occurs in this protein, we have studied its reduction by external photoreduced flavin by using pulsed-laser excitation. This approach allows us to measure reduction kinetics on the mirosecond time scale. Both fully reduced lumiflavin and lumiflavin semiquinone radical reduce cytochrome c-552 with second-order rate constants of approximately 1.4 x 10(6) M-1s-1 and 1.9 x 10(8) M-1 s-1, respectively. Kinetic and spectral data and the results of similar studies with riboflavin indicate that both the flavin and heme moieties of cytochrome c-552 are reduced simultaneously on a millisecond time scale, with the transient formation of a protein-bound flavin anion radical. This is suggested to be due to rapid intramolecular electron transfer. Further, steric restrictions play an important role in the reduction reaction. Studies were conducted on the redox processes following photolysis of CO-ferrocytochrome c-552 in which the flavin was partly oxidized to resolve the kinetics of electron transfer between the heme and flavin of cytochrome c-552. Based on these results, we conclude that intramolecular electron transfer from ferrous heme to oxidized flavin occurs with a first-order rate constant of greater than 1.4 x 10(6) s-1.     

Interaction of an anticancer ruthenium complex HInd[RuInd2Cl4] with cytochrome c

Cytochrome c is an important electron transfer protein in the respiratory chain, shuttling electrons from cytochrome c reductase to cytochrome c oxidase. Extensive chemical modification studies indicate significant electrostatic interactions between these proteins and show that all structural and conformational changes of cytochrome c can influence the electron transport. In the present work we examine the effect of an anticancer ruthenium complex, trans-Indazolium (bisindazole) tetrachlororuthenate(III) (HInd[RuInd(2)Cl(4)]), on the conformation of cytochrome c, the state of the heme moiety, formation of the protein dimer and on the folding state of apocytochrome c. For this purpose, gel-filtration chromatography, absorption second derivative spectroscopy, circular dichroism (CD) and inductively coupled plasma atomic emission spectroscopy (ICP(AES)) were used. The present data have revealed that binding of the potential anticancer drug HInd[RuInd(2)Cl(4)] complex to cytochrome c induces a conformation of the protein with less organized secondary and tertiary structure.     

Conformational dynamics and molecular interaction reactions of recombinant cytochrome p450scc (CYP11A1) detected by fluorescence energy transfer.

Bovine adrenocortical cytochrome P450scc (P450scc) was expressed in Escherichia coli and purified as the substrate bound, high-spin complex (16.7 nmol of heme per mg of protein, expression level in E. coli about 400-700 nmol/l). The recombinant protein was characterized by comparison with native P450scc purified from adrenal cortex mitochondria. To study the interaction of the electron transfer proteins during the functioning of the heme protein, recombinant P450scc was selectively modified with fluorescein isothiocyanate (FITC). The present paper shows that modified P450scc, purified by affinity chromatography using adrenodoxin-Sepharose to remove non-covalently bound FITC, retains the functional activity of the unmodified enzyme, including its ability to bind adrenodoxin. Based on the efficiency of resonance fluorescence energy transfer in the donor-acceptor pair, FITC-heme, we calculated the distance between Lys(338), selectively labeled with the dye, and the heme of P450scc. The intensity of fluorescence from the label dramatically changes during: (a) denaturation of P450scc; (b) changing the spin state or redox potential of the heme protein; (c) formation of the carbon monoxide complex of reduced P450scc; (d) as well as during reactions of intermolecular interactions, such as changes of the state of aggregation, complex formation with the substrate, binding to the electron transfer partner adrenodoxin, or insertion of the protein into an artificial phospholipid membrane. Selective chemical modification of P450scc with FITC proved to be a very useful method to study the dynamics of conformational changes of the recombinant heme protein. The data obtained indicate that functionally important conformational changes of P450scc are large-scale ones, i.e. they are not limited only to changes in the dynamics of the protein active center. The results of the present study also indicate that chemical modification of Lys(338) of bovine adrenocortical P450scc does not dramatically alter the activity of the heme protein, but does result in a decrease of protein stability.     

Assembly of a transmembrane b-type cytochrome is mainly driven by transmembrane helix interactions

Folding, assembly and stability of alpha-helical membrane proteins is still not very well understood. Several of these membrane proteins contain cofactors, which are essential for their function and which can be involved in protein assembly and/or stabilization. The effect of heme binding on the assembly and stability of the transmembrane b-type cytochrome b'559 was studied by fluorescence resonance energy transfer. Cytochrome b'559 consists of two monomers of a 44 amino acid long polypeptide, which contains one transmembrane domain. The synthesis of two variants of the b'559 monomer, each carrying a specific fluorescent dye, allowed monitoring helix-helix interactions in micelles by resonance energy transfer. The measurements demonstrate that the transmembrane peptides dimerize in detergent in the absence and presence of the heme cofactor. Cofactor binding only marginally enhances dimerization and, apparently, the redox state of the heme group has no effect on dimerization.     

Cytochrome P-450scc-adrenodoxin interactions. Ionic effects on binding, and regulation of cytochrome reduction by bound steroid substrates

The binding of adrenodoxin to cytochrome P-450scc and the intracomplex electron transfer from the iron-sulfur center to the heme have been studied. Salt sensitivity of the protein complex suggests the participation of electrostatic forces, as is also seen for the complex of adrenodoxin with NADPH-adrenodoxin reductase. Differences in ion specificities for the complexes of adrenodoxin with the other two proteins suggest some differences in binding requirements. Insensitivity of the heme reduction to solution conditions (salt, detergent) and kinetic analysis indicate that the protein complex is formed rapidly and that intracomplex electron transfer then occurs more slowly. Factors governing the rate of this electron transfer were investigated; binding of a series of cholesterol derivatives was used to perturb the spin state, midpoint potential, and reduction rate of the heme, and thus to test for relationships among these parameters. A linear free energy relationship between the substrate-induced midpoint potential and reduction rate is seen, but none of the other parameters (including the strength of substrate binding) are correlated. Data indicate that factors other than spin state (i.e. steric requirements and bonding groups within the steroid-binding site) regulate the strength of steroid binding. The bound steroid then modulates both midpoint potential/reduction rate and spin state but by independent mechanisms.