The medium reorganization energy for the charge transfer reactions in proteins

A low static dielectric permittivity of proteins causes the low reorganization energies for the charge transfer reactions inside them. This reorganization energy does not depend on the pre-existing intraprotein electric field. The charge transferred inside the protein interacts with its aqueous surroundings; for many globular proteins, the effect of this surroundings on the reorganization energy is comparable with the effect of reorganization of the protein itself while for the charge transfer in the middle of membrane the aqueous phase plays a minor role. Reorganization energy depends strongly on the system considered, and hence there is no sense to speak on the "protein reorganization energy" as some permanent characteristic parameter. We employed a simple algorithm for calculation of the medium reorganization energy using the numerical solution of the Poisson-Boltzmann equation. Namely, the reaction field energy was computed in two versions - all media having optical dielectric permittivity, and all the media with the static one; the difference of these two quantities gives the reorganization energy. We have calculated reorganization energies for electron transfer in cytochrome c, various ammine-ruthenated cytochromes c, azurin, ferredoxin, cytochrome c oxidase, complex of methylamine dehydrogenase with amicyanin, and for proton transfer in α-chymotrypsin. It is shown that calculation of the medium reorganization energy can be a useful tool in analysis of the mechanisms of the charge transfer reactions in proteins.     

Voltammetric probes of cytochrome electroreactivity: the effect of the protein matrix on outer-sphere reorganization energy and electronic coupling probed through comparisons with the behavior of porphyrin complexes

Using surface-modified electrodes composed of omega-hydroxyalkanethiols, an experimentally based value for the inner-sphere reorganization energy of the bis(imidazole)iron porphyrin system has been obtained by examining the solvent dependence of the reorganization energy of bis(N-methylimidazole)meso-tetraphenyl iron porphyrin. The value obtained (0.41 +/- 0.06 eV) is remarkably similar to values we have recently reported for the reorganization energy of cytochrome b(5) (0.43 +/- 0.02 eV) and cytochrome c (0.58 +/- 0.06 eV). This strongly suggests that the protein matrix mimics the behavior of a low dielectric solvent and effectively shields the heme from the solvent. The effect of the orientation of the heme relative to the electrode was also explored by sytematically varying the steric bulk of the axial ligands. On the basis of a good linear correlation between the electronic coupling and the cosine of the angle between the heme plane and the surface of the electrode, it is suggested that a parallel orientation of the heme yields a maximum in the electronic coupling. Relevance to interheme protein electron transfer is discussed.     

Role of the surface-exposed leucine 155 in the metal ion binding loop of the CuA domain of cytochrome c oxidase from Thermus thermophilus on the function and stability of the protein

The role of Leu155 in the metal ion binding loop in the soluble CuA binding domain of subunit II of cytochrome c oxidase from Thermus thermophilus (TtCuA) was investigated by site-specific mutations of this residue to arginine (L155R) and glutamic acid (L155E). The UV-visible absorption and electron paramagnetic resonance spectra suggested that the Cu(2)S(2) core of TtCuA was almost unchanged by the mutations. The redox potential of the metal center in the L155R mutant was ~20 mV higher than that in the WT protein, while that of the L155E mutant was almost the same as that of the wild type (WT-TtCuA). The rate of transfer of an electron from cytochrome c(552) to the L155E mutant was much lower than that of transfer to the WT protein, while that for transfer to the L155R mutant was similar to that of WT-TtCuA. The total reorganization energy was increased for both the mutant proteins compared to WT-TtCuA. The results suggest that the presence of a negatively charged residue at the site of Leu155 in TtCuA possibly disfavors the protein-protein interaction between the two redox partners. The mutation also affected the equilibrium pH dependence of the protein. The thermal and thermodynamic stability of TtCuA was drastically decreased upon the mutation, which is most prominent in the L155R mutant. These studies indicate that the hydrophobic patch at the surface of TtCuA consisting of Leu155 is important for the transfer of an electron between cytochrome c(552) and TtCuA.     

Fast structural dynamics in reduced and oxidized cytochrome c

The sub‐nanosecond structural dynamics of reduced and oxidized cytochrome c were characterized. Dynamic properties of the protein backbone measured by amide ¹⁵N relaxation and side chains measured by the deuterium relaxation of methyl groups change little upon change in the redox state. These results imply that the solvent reorganization energy associated with electron transfer is small, consistent with previous theoretical analyses. The relative rigidity of both redox states also implies that dynamic relief of destructive electron transfer pathway interference is not operational in free cytochrome c.     

Kinetics of Electron Transfer within Cytochrome bc 1 and Between Cytochrome bc 1 and Cytochrome c

In this minireview an overview is presented of the kinetics of electron transfer within the cytochrome bc (1) complex, as well as from cytochrome bc (1) to cytochrome c. The cytochrome bc (1) complex (ubiquinone:cytochrome c oxidoreductase) is an integral membrane protein found in the mitochondrial respiratory chain as well as the electron transfer chains of many respiratory and photosynthetic bacteria. Experiments on both mitochondrial and bacterial cyatochrome bc (1) have provided detailed kinetic information supporting a Q-cycle mechanism for electron transfer within the complex. On the basis of X-ray crystallographic studies of cytochrome bc (1), it has been proposed that the Rieske iron-sulfur protein undergoes large conformational changes as it transports electrons from ubiquinol to cytochrome c (1). A new method was developed to study electron transfer within cytochrome bc (1) using a binuclear ruthenium complex to rapidly photooxidize cytochrome c (1). The rate constant for electron transfer from the iron-sulfur center to cytochrome c (1) was found to be 80,000 s(-1), and is controlled by the dynamics of conformational changes in the iron-sulfur protein. Moreover, a linkage between the conformation of the ubiquinol binding site and the conformational dynamics of the iron-sulfur protein has been discovered which could play a role in the bifurcated oxidation of ubiquinol. A ruthenium photoexcitation method has also been developed to measure electron transfer from cytochrome c (1) to cytochrome c. The kinetics of electron transfer are interpreted in light of a new X-ray crystal structure for the complex between cytochrome bc (1) and cytochrome c.     

How does reorganization energy change upon protein unfolding? Monitoring the structural perturbations in the heme cavity of cytochrome c

In several classes of proteins the redox center provides an additional intrinsic biophysical probe that could be used to study the protein structure and function. In present report reorganization energy (lambda, as a parameter describing electron transfer properties) was used to study the protein structural changes around the heme prosthetic group in cytochrome c (cyt c). We attempted to monitor the value of this parameter upon the unfolding process of cyt c by urea, during which it was increased sigmoidally from about 0.52 to 0.82 eV for native and unfold protein, respectively. Results indicate that by structural changes in the heme site, lambda provides a complementary tool for following the unfolding process. Assuming a reversible two-state model for cyt c unfolding, Delta G(H2O), Cm and m values were determined to be 8.32+/-0.7 kcal mol(-1), 1.53+/-0.19 kcalmol(-1)M(-1) and 5.03 M, respectively.     

Reverse electron transfer from the cytochrome c level in cyanide-resistant mitochondria of the yeast, Candida lipolytica]

The ability of cyanide-resistant mitochondria of yeast Candida lipolytica to perform reverse electron transfer from cytochrome c to alternative oxidase was studied. It was shown that the energy for such a transfer can be provided by high energy intermediates or membrane potential but not by ATP. Reverse electron transfer from cytochrome c is impossible due to energy of NADH and alpha-glycerophosphate oxidation via alternative pathway in the presence of cyanide. These results prove once again that electron transfer via alternative pathway is not connected with the energy accumulation.     

Role of the hinge protein in the electron transfer between cardiac cytochrome c1 and c. Equilibrium constants and kinetic probes

A role of the hinge protein is studied in the electron transfer reaction between cytochromes c1 and c, using highly purified "one-band" cytochrome c1 and "two-band" cytochrome c1. The results show that the hinge protein (Hp), which is essential for a stable ionic strength-sensitive c1-Hp-c complex, seems to play a certain role in electron transfer between cytochromes c1 and c; Keq for electron transfer reaction between cytochromes c1 and c in the presence of the hinge protein is found to be about 40% higher than that in the absence of the hinge protein at low ionic strength, but no difference exists at high ionic strength. We propose a hypothesis that the hinge protein may function as regulator for the electron transfer reaction between cytochromes c1 and c, and this may be at least one of the roles of the hinge protein in mitochondria.     

Insights from the structure of the yeast cytochrome bc1 complex: crystallization of membrane proteins with antibody fragments

The ubiquinol:cytochrome c oxidoreductase (EC 1.20.2.2, QCR or cytochrome bc1 complex) is a component of respiratory and photosynthetic electron transfer chains in mitochondria and bacteria. The complex transfers electrons from quinol to cytochrome c. Electron transfer is coupled to proton translocation across the lipid bilayer, thereby generating an electrochemical proton gradient, which conserves the free energy of the redox reaction. The yeast complex was crystallized with antibody Fv fragments, a promising technique to obtain well-ordered crystals from membrane proteins. The high-resolution structure of the yeast protein reveals details of the catalytic sites of the complex, which are important for electron and proton transfer.     

Function of the iron-sulfur protein of the cytochrome b-c1 segment in electron transfer reactions of the mitochondrial respiratory chain

Resolution and reconstitution has been used to examine the involvement of the iron-sulfur protein of the cytochrome b-c1 segment in electron transfer reactions in this region of the mitochondrial respiratory chain. The iron-sulfur protein is required for electron transfer from succinate and from ubiquinol to cytochrome c1. It is not required for reduction of cytochrome b under these conditions, but it is required for oxidation of cytochrome b by cytochrome c plus cytochrome c oxidase. Removal of the iron-sulfur protein from the b-c1 complex prevents reduction of both cytochromes b and c1 by succinate or ubiquinol if antimycin is added to the depleted complex. As increasing amounts of iron-sulfur protein are reconstituted to the depleted complex, the amounts of cytochromes b and c1 reduced by succinate in the presence of antimycin increase and closely parallel the amounts of ubiquinol-cytochrome c reductase activity restored to the reconstituted complex, measured before addition of antimycin. The function of the iron-sulfur protein in these oxidation-reduction reactions is consistent with a cyclic pathway of electron transfer through the cytochrome b-c1 complex, in which the iron-sulfur protein functions as a ubiquinol-cytochrome c1/ubisemiquinone-cytochrome b oxidoreductase.     

Understanding the mechanism of proton movement linked to oxygen reduction in cytochrome c oxidase: lessons from other proteins

Cytochrome c oxidase is a large intrinsic membrane protein designed to use the energy of electron transfer and oxygen reduction to pump protons across a membrane. The molecular mechanism of the energy conversion process is not understood. Other proteins with simpler, better resolved structures have been more completely defined and offer insight into possible mechanisms of proton transfer in cytochrome c oxidase. Important concepts that are illustrated by these model systems include the ideas of conformational change both close to and at a distance from the triggering event, and the formation of a transitory water-linked proton pathway during a catalytic cycle. Evidence for the applicability of these concepts to cytochrome c oxidase is discussed.     

Mapping the electron transfer interface between cytochrome b5 and cytochrome c

To characterize the cytochrome b(5) (Cyt b(5))-cytochrome c (Cyt c) interactions during electron transfer, variants of Cyt b(5) have been employed to assess the contributions of electrostatic interactions (substitution of surface charged residues Glu44, Glu48, Glu56, and Asp60 and heme propionate), hydrophobic interactions, and the thermodynamic driving forces (substitutions for hydrophobic residues in heme pocket residues Phe35, Pro40, Val45, Phe58, and Val61). The electrostatic interactions play an important role in maintaining the stability and specificity of the Cyt b(5)-Cyt c complex that is formed. There is no essential effect on the intraprotein complex electron transfer even if most of the involved negatively charged residues on the surface of Cyt b(5) have been removed. The results support a dynamic docking paradigm for Cyt b(5)-Cyt c interactions. The orientation that is optimal for binding may not be optimal form for electron transfer. Substitution of hydrophobic residues does not have a significant effect on the binding between Cyt b(5) and Cyt c; rather, it regulates the electron transfer rates via changes in the driving force. Combining the electron transfer studies of the Cyt b(5)-Cyt c system and the Cyt b(5)-Zn-Cyt c system, we obtain the reorganization energy (0.6 eV) at an ionic strength of 150 mM.     

The novel cytochrome c6 of chloroplasts: a case of evolutionary bricolage?

Cytochrome c6 has long been known as a redox carrier of the thylakoid lumen of cyanobacteria and some eukaryotic algae that can substitute for plastocyanin in electron transfer. Until recently, it was widely accepted that land plants lack a cytochrome c6. However, a homologue of the protein has now been identified in several plant species together with an additional isoform in the green alga Chlamydomonas reinhardtii. This form of the protein, designated cytochrome c6A, differs from the 'conventional' cytochrome c6 in possessing a conserved insertion of 12 amino acids that includes two absolutely conserved cysteine residues. There are conflicting reports of whether cytochrome c6A can substitute for plastocyanin in photosynthetic electron transfer. The evidence for and against this is reviewed and the likely evolutionary history of cytochrome c6A is discussed. It is suggested that it has been converted from a primary role in electron transfer to one in regulation within the chloroplast, and is an example of evolutionary 'bricolage'.     

Rate of transmembrane electron transfer in chromaffin-vesicle ghosts

The chromaffin vesicle of the adrenal medulla contains a transmembrane electron carrier that may provide reducing equivalents for dopamine beta-hydroxylase in vivo. This electron-transfer system can be assayed by trapping ascorbic acid inside resealed membrane vesicles (ghosts), adding an external electron acceptor such as ferricytochrome c or ferricyanide, and following the reduction of these acceptors spectrophotometrically. Cytochrome c reduction is more rapid at high pH and is proportional to the amount of chromaffin-vesicle ghosts, at least at low ghost concentrations. At pH 7.0, ghosts loaded with 100 mM ascorbic acid reduce 60 microM cytochrome c at a rate of 0.035 +/- 0.010 mu equiv min-1 (mg of protein)-1 and 200 microM ferricyanide at a rate of 2.3 +/- 0.3 mu equiv min-1 (mg of protein)-1. The rate of cytochrome c reduction is accelerated to 0.105 +/- 0.021 mu equiv min-1 (mg of protein)-1 when cytochrome c is pretreated with equimolar ferrocyanide. Pretreatment of cytochrome c with ferricyanide also causes a rapid rate of reduction, but only after an initial delay. The ferrocyanide-stimulated rate of cytochrome c reduction is further accelerated by the protonophore carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP), probably because FCCP dissipates the membrane potential generated by electron transfer. These rates of electron transfer are sufficient to account for electron transfer to dopamine beta-hydroxylase in vivo and are consistent with the mediation of electron transfer by cytochrome b-561.     

Electron transfer between liposomal cytochrome c1 and cytochrome c: catalytic implications of electrostatic potentials

Kinetics measurements of the electron transfer between ferricytochrome c and liposomal ferrocytochrome c1 (with and without the hinge protein) were performed. The observed rate constants(kobs) of electron transfer between liposomal ferrocytochrome c1 and ferricytochrome c at different ionic strengths were measured in cacodylate buffer, pH 7.4, at 2 C. The effect of ionic strength on the rate constant(kobs) of electron transfer between liposomal cytochrome c1 and cytochrome c is far greater than that in the solution kinetics (Kim, C.H., Balny, C. and King, T.E. (1987) J. Biol. Chem. 262, 8103-8108). The result demonstrates that the membrane bound cytochrome c1 creates a polyelectrolytic microenvironment which appears to be involved in the control of electron transfer and can be modulated by the ionic strength. The involvement of electrostatic potentials in the electron transfer between the membrane bound cytochrome c1 and cytochrome c is discussed in accord with the experimental results and a polyelectrolyte theory.     

Role of the conserved arginine pair in proton and electron transfer in cytochrome C oxidase

A hydrogen-bonded network is observed above the hemes in all of the high-resolution crystal structures of cytochrome oxidases. It includes water and a pair of arginines, R481 and R482 (Rhodobacter sphaeroides numbering), that interact directly with heme a and the heme a(3) propionates. The hydrogen-bonded network provides potential pathways for proton release. The arginines, and the backbone peptide bond between them, have also been proposed to form part of a facilitated electron transfer route between Cu(A) and heme a. Our studies show that mutations of R482 (K, Q, and A) and R481 (K) retain substantial activity and are able to pump protons, but at somewhat reduced rates and stoichiometries. A slowed rate of electron transfer from cytochrome c to Cu(A) suggests a change in the orientation of cytochrome c binding in all but the R to K mutants. The mutant R482P is more perturbed in its structure and is altered in the redox potential difference between heme a and Cu(A): +18 mV for R482P and +46 mV for the wild type (heme a - Cu(A)). The electron transfer rate between Cu(A) and heme a is also altered from 93000 s(-1) in the wild type to 50 s(-1) in the oxidized R482P mutant, reminiscent of changes observed in a Cu(A)-ligand mutant, H260N. In neither case is the approximately 2000-fold change in the rate accounted for by the altered redox potentials, suggesting that both cause a major modification in the path or reorganization energy of electron transfer.     

Characterization of horse cytochrome c expressed in Escherichia coli.

We have expressed horse cytochrome c in Escherichia coli. The gene was designed with E. coli codon bias and assembled by using a recursive polymerase chain reaction method. The far-ultraviolet and near-ultraviolet/Soret circular dichroism (CD) spectra show that the structure of recombinant horse cytochrome c is the same as that of the authentic protein. CD-detected thermal denaturation studies were used to measure the thermodynamic parameters associated with two-state denaturation. The free energy of denaturation for the recombinant protein is 10.0 +/- 2.3 kcal mol(-1) at pH 4.6 and 25 degrees C, which agrees with the value for the authentic protein. The expression system will help advance our understanding of the roles of cytochrome c in electron transfer, oxidative stress, and apoptosis by allowing the production of protein variants.     

Formamide probes a role for water in the catalytic cycle of cytochrome c oxidase

Formamide is a slow-onset inhibitor of mitochondrial cytochrome c oxidase that is proposed to act by blocking water movement through the protein. In the presence of formamide the redox level of mitochondrial cytochrome c oxidase evolves over the steady state as the apparent electron transfer rate from cytochrome a to cytochrome a(3) slows. At maximal inhibition cytochrome a and cytochrome c are fully reduced, whereas cytochrome a(3) and Cu(B) remain fully oxidized consistent with the idea that formamide interferes with electron transfer between cytochrome a and the oxygen reaction site. However, transient kinetic studies show that intrinsic rates of electron transfer are unchanged in the formamide-inhibited enzyme. Formamide inhibition is demonstrated for another member of the heme-oxidase family, cytochrome c oxidase from Bacillus subtilis, but the onset of inhibition is much quicker than for mitochondrial oxidase. If formamide inhibition arises from a steric blockade of water exchange during catalysis then water exchange in the smaller bacterial oxidase is more open. Subunit III removal from the mitochondrial oxidase hastens the onset of formamide inhibition suggesting a role for subunit III in controlling water exchange during the cytochrome c oxidase reaction.     

Structural control of electron-transfer properties in metalloproteins

Summary The factors that control long-range electron transfer between two redox centers in a protein are summarized. Rack-induced bonding in blue copper proteins is described. The protein conformation forces the Cu(II) ion into a distorted geometry, lying at least 70 kJ mol^–1 above the preferred square-planar geometry in energy. The distortion has the effect that the structural change associated with electron transfer is minimal and thus the reorganization energy small. Variations in back bonding are suggested to modulate the reduction potentials of blue proteins without any change in the energy of the charge-transfer transitions. In proton pumps there must be a structural control of the electron transfer rates (electron gating) and model studies suggest that this is best achieved by variations in the reorganization energy.     

Definition of the interaction domain for cytochrome c on cytochrome c oxidase. III. Prediction of the docked complex by a complete, systematic search

The electron transfer complex between bovine cytochrome c oxidase and horse cytochrome c has been predicted with the docking program DOT, which performs a complete, systematic search over all six rotational and translational degrees of freedom. Energies for over 36 billion configurations were calculated, providing a free-energy landscape showing guidance of positively charged cytochrome c to the negative region on the cytochrome c oxidase surface formed by subunit II. In a representative configuration, the solvent-exposed cytochrome c heme edge is within 4 A of the indole ring of subunit II residue Trp(104), indicating a likely electron transfer path. These two groups are surrounded by a small, hydrophobic contact region, which is surrounded by electrostatically complementary hydrophilic interactions. Cytochrome c/cytochrome c oxidase interactions of Lys(13) with Asp(119) and Lys(72) with Gln(103) and Asp(158) are the most critical polar interactions due to their proximity to the hydrophobic region and exclusion from bulk solvent. The predicted complex matches previous mutagenesis, binding, and time-resolved kinetics studies that implicate Trp(104) in electron transfer and show the importance of specific charged residues to protein affinity. Electrostatic forces not only enhance long range protein/protein association; they also predominate in short range alignment, creating the transient interaction needed for rapid turnover.