Laser flash photolysis studies of electron transfer to the cytochrome b5-cytochrome c complex

Unveiling the details of electron transfer in multicenter redox proteins

Metalloproteins modulate the intrinsic properties of transition metals to achieve controlled catalysis, electron transfer, or structural stabilization. Those performing electron transport, redox proteins, are a diverse class of proteins with central roles in numerous metabolic and signaling pathways, including respiration and photosynthesis. Many redox proteins have applications in industry, especially biotechnology, making them the focus of intense research. Redox proteins may contain one or multiple redox centers of the same or a different type. The complexity of proteins with multiple redox centers makes it difficult to establish a detailed molecular mechanism for their activity. Thermodynamic and kinetic information can be interpreted using the molecular structure to elucidate the protein's functional mechanism. This Account reviews experimental strategies developed in recent years to determine the detailed thermodynamic properties of multicenter redox proteins and their kinetic properties during interactions with redox partners. These strategies allow the discrimination of thermodynamic and kinetic properties of each individual redox center. The thermodynamic characterization of the redox transitions results from the combined analysis of data from NMR and UV-visible spectroscopy. Meanwhile, the kinetic characterization of intermolecular electron transfer comes from stopped-flow spectrophotometry. We illustrate an application of these strategies to a particular redox protein, the small tetraheme cytochrome from the periplasmic space of Shewanella oneidensis MR-1. This protein is a convenient prototype for developing methods for the detailed analysis of multicenter electron transfer proteins because hemes have strong UV-visible absorption bands and because heme resonances have exquisite discrimination in NMR spectra. Nonetheless, the methods are fully generalizable. Ultimately, this Account highlights the relevance of detailed characterization of the thermodynamic and kinetic properties of redox proteins. These properties are responsible for the directionality and specificity of the electron transfer process in bioenergetic pathways; a more thorough characterization of these properties should allow better-designed proteins for industrial applications.

Electrochemistry of redox-active self-assembled monolayers

Redox-active self-assembled monolayers (SAMs) provide an excellent platform for investigating electron transfer kinetics. Using a well-defined bridge, a redox center can be positioned at a fixed distance from the electrode and electron transfer kinetics probed using a variety of electrochemical techniques. Cyclic voltammetry, AC voltammetry, electrochemical impedance spectroscopy, and chronoamperometry are most commonly used to determine the rate of electron transfer of redox-activated SAMs. A variety of redox species have been attached to SAMs, and include transition metal complexes (e.g., ferrocene, ruthenium pentaammine, osmium bisbipyridine, metal clusters) and organic molecules (e.g., galvinol, C(60)). SAMs offer an ideal environment to study the outer-sphere interactions of redox species. The composition and integrity of the monolayer and the electrode material influence the electron transfer kinetics and can be investigated using electrochemical methods. Theoretical models have been developed for investigating SAM structure. This review discusses methods and monolayer compositions for electrochemical measurements of redox-active SAMs.

Electron flow through metalloproteins

Electron transfers in photosynthesis and respiration commonly occur between metal-containing cofactors that are separated by large molecular distances. Understanding the underlying physics and chemistry of these biological electron transfer processes is the goal of much of the work in our laboratories. Employing laser flash-quench triggering methods, we have shown that 20A, coupling-limited Fe(II) to Ru(III) and Cu(I) to Ru(III) electron tunneling in Ru-modified cytochromes and blue copper proteins can occur on the microsecond timescale both in solutions and crystals; and, further, that analysis of these rates suggests that distant donor-acceptor electronic couplings are mediated by a combination of sigma and hydrogen bonds in folded polypeptide structures. Redox equivalents can be transferred even longer distances by multistep tunneling, often called hopping, through intervening amino acid side chains. In recent work, we have found that 20A hole hopping through an intervening tryptophan is several hundred-fold faster than single-step electron tunneling in a Re-modified blue copper protein.

Phospholipid membranes affect tertiary structure of the soluble cytochrome b5 heme-binding domain

The influence of charged phospholipid membranes on the conformational state of the water-soluble fragment of cytochrome b5 has been investigated by a variety of techniques at neutral pH. The results of this work provide the first evidence that aqueous solutions with high phospholipid/protein molar ratios (pH 7.2) induce the cytochrome to undergo a structural transition from the native conformation to an intermediate state with molten-globule like properties that occur in the presence of an artificial membrane surface and that leads to binding of the protein to the membrane. At other phospholipid/protein ratios, equilibrium was observed between cytochrome free in solution and cytochrome bound to the surface of vesicles. Inhibition of protein binding to the vesicles with increasing ionic strength indicated for the most part an electrostatic contribution to the stability of cytochrome b5-vesicle interactions at pH 7.2. The possible physiological role of membrane-induced conformational change in the structure of cytochrome b5 upon the interaction with its redox partners is discussed.

Long-range electron transfer

Recent investigations have shed much light on the nuclear and electronic factors that control the rates of long-range electron tunneling through molecules in aqueous and organic glasses as well as through bonds in donor-bridge-acceptor complexes. Couplings through covalent and hydrogen bonds are much stronger than those across van der Waals gaps, and these differences in coupling between bonded and nonbonded atoms account for the dependence of tunneling rates on the structure of the media between redox sites in Ru-modified proteins and protein-protein complexes.

Intramolecular electron transfer in a bacterial sulfite dehydrogenase

Sulfite dehydrogenase (SDH) from Starkeya novella, a sulfite-oxidizing molybdenum-containing enzyme, has a novel tightly bound alphabeta-heterodimeric structure in which the Mo cofactor and the c-type heme are located on different subunits. Flash photolysis studies of intramolecular electron transfer (IET) in SDH show that the process is first-order, independent of solution viscosity, and not inhibited by sulfate, which strongly indicates that IET in SDH proceeds directly through the protein medium and does not involve substantial movement of the two subunits relative to each other. The IET results for SDH contrast with those for chicken and human sulfite oxidase (SO) in which the molybdenum domain is linked to a b-type heme domain through a flexible loop, and IET shows a remarkable dependence on sulfate concentration and viscosity that has been ascribed to interdomain docking. The results for SDH provide additional support for the interdomain docking hypothesis in animal SO and clearly demonstrate that dependence of IET on viscosity and sulfate is not an inherent property of all sulfite-oxidizing molybdenum enzymes.

The FMN to heme electron transfer in cytochrome P450BM-3. Effect of chemical modification of cysteines engineered at the FMN-heme domain interaction site

The crystal structure of the complex between the heme and FMN-containing domains of Bacillus megaterium cytochrome P450BM-3 (Sevrioukova, I. F., Li, H., Zhang, H., Peterson, J. A., and Poulos, T. L. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 1863-1868) indicates that the proximal side of the heme domain molecule is the docking site for the FMN domain and that the Pro(382)-Gln(387) peptide may provide an electron transfer (ET) path from the FMN to the heme iron. In order to evaluate whether ET complexes formed in solution by the heme and FMN domains are structurally relevant to that seen in the crystal structure, we utilized site-directed mutagenesis to introduce Cys residues at positions 104 and 387, which are sites of close contact between the domains in the crystal structure and at position 372 as a control. Cys residues were modified with a bulky sulfhydryl reagent, 1-dimethylaminonaphthalene-5-sulfonate-L-cystine (dansylcystine (DC)), to prevent the FMN domain from binding at the site seen in the crystal structure. The DC modification of Cys(372) and Cys(387) resulted in a 2-fold decrease in the rates of interdomain ET in the reconstituted system consisting of the separate heme and FMN domains and had no effect on heme reduction in the intact heme/FMN-binding fragment of P450BM-3. DC modification of Cys(104) caused a 10-20-fold decrease in the interdomain ET reaction rate in both the reconstituted system and the intact heme/FMN domain. This indicates that the proximal side of the heme domain molecule represents the FMN domain binding site in both the crystallized and solution complexes, with the area around residue 104 being the most critical for the redox partner docking.

Negatively charged anabaena flavodoxin residues (Asp144 and Glu145) are important for reconstitution of cytochrome P450 17alpha-hydroxylase activity

Catalysis by microsomal cytochromes P450 requires the membrane-bound enzyme NADPH-cytochrome P450 reductase (P450 reductase), which transfers electrons to the P450 heme via a flavodoxin-like domain. Previously, we reported that Escherichia coli flavodoxin (Fld), a soluble electron transfer protein, directly interacts with bovine cytochrome P450 17alpha-hydroxylase/17,20-lyase (P450c17) and donates electrons to this enzyme when reconstituted with NADPH-ferredoxin (flavodoxin) reductase (FNR) (Jenkins, C. M., and Waterman, M. R. (1994) J. Biol. Chem. 269, 27401-27408). To investigate whether flavodoxins can serve as useful models of the analogous domain in P450 reductase, we have examined the FNR-Fld system from the cyanobacterium Anabaena. Mutagenesis of two acidic Anabaena Fld residues (D144A and E145A) significantly decreased flavodoxin-supported P450c17 progesterone 17alpha-hydroxylase activity. Specifically, D144A exhibited only 15% of the activity of wild-type Fld, whereas the adjacent mutation, E145A, caused a 40% loss in activity. P450-dependent hydrogen peroxide/superoxide production by wild-type FNR-Fld was measurably higher than that generated by FNR-D144A or FNR-E145A, indicating that the mutations do not lead to P450 heme-mediated electron uncoupling. Interestingly, the D144A and E145A mutants bind with equal or even greater affinity to P450c17 than wild-type Fld. Furthermore, these mutations (D144A and E145A) actually increased cytochrome c reductase activity (35 and 100% higher than wild type). Anabaena Fld residues Asp144 and Glu145 align closely with rat P450 reductase residue Asp208, which has been shown by mutagenesis to be important in electron transfer to P4502B1 but not to cytochrome c (Shen, A. L., and Kasper, C. B. (1995) J. Biol. Chem. 270, 27475-27480). Thus, these residues in flavodoxins and P450 reductase appear to have similar functions in P450 recognition and/or electron transfer, supporting the hypothesis that flavodoxins represent valid models for the FMN-binding domain of P450 reductase.

Molecular dynamics simulation of cytochrome b5: implications for protein-protein recognition

Cytochrome b5 participates in electron-transfer reactions with a variety of different proteins. To explore how this protein might discern between structurally varied proteins, we have performed a molecular dynamics simulation focusing on its structural stability and dynamic behavior in solution. The protein was simulated in water at 298 K and pH 6.9 for 2.5 ns. The protein deviated significantly from the crystal structure midway through the simulation, but ultimately the crystalline conformation was regained. The simulation was at all times well behaved as judged by comparison to structural NMR data obtained in solution. One region of the protein backbone that deviated from the crystal conformation contains acidic residues implicated in electrostatic-based protein-protein recognition. The mobility in this region caused the protein to display different patterns of residues at the surface with time, as well as the formation of a large cleft partially exposing the hydrophobic core lining the heme pocket. Furthermore, the position and cyclical formation of this cleft suggest that hydrophobic interactions may be important in protein-protein recognition events and possibly even electron transfer, as the cleft allows for easy access to the heme group. These results indicate that thermal motion could provide a low-energy mechanism for controlling recognition events. Thus, the dynamical behavior observed through the varying solution conformations sampled may be important in influencing the diverse range of protein-protein interactions in which cytochrome b5 participates.

Experimental and theoretical analysis of the interaction between cytochrome c and cytochrome b5

Experimental and theoretical investigation of the interaction of cytochrome c and cytochrome b5 performed over nearly twenty years has produced considerable insight into the manner in which these proteins recognize and bind to each other. The results of these studies and the experimental and theoretical strategies that have been developed to achieve these results have significant implications for understanding the behavior of similar complexes formed by more complex and less-well characterized electron transfer proteins. The current review provides a comprehensive summary and critical evaluation of the literature on which the current status of our understanding of the interaction of cytochrome c and cytochrome b5 is based. The general issues related to the study of electron transfer complexes of this type are discussed and some new directions for future investigation of such systems are considered.

Electron transfer from cytochrome b5 to cytochrome c

The reaction of cytochrome b5 with cytochrome c has become a very prominent system for investigating fundamental questions regarding interprotein electron transfer. One of the first computer modeling studies of electron transfer and protein/protein interaction was reported using this system. Subsequently, numerous studies focused on the experimental determination of the features which control protein/protein interactions. Kinetic measurements of the intracomplex electron transfer reaction have only appeared in the last 10 years. The current review will provide a summary of the kinetic measurements and a critical assessment of the interpretation of these experiments.

Structure-function relationships in the ferredoxin/ferredoxin: NADP+ reductase system from Anabaena

We have used a combination of laser flash photolysis time-resolved spectrophotometry and site-specific mutagenesis of surface amino acid residues to investigate the structural factors which influence electron transfer from Anabaena ferredoxin to its physiological partner ferredoxin-NADP+ reductase. Two ferredoxin residues (E94 and F65) are found to be highly critical interaction sites, whereas other nearby residues are found to be either inconsequential or to have only moderate effects. Basic residues near the N-terminus of the reductase are also found to exert a significant influence on interprotein electron transfer. The mechanistic implications of these results are discussed.

Biological electron transfer: structural and mechanistic studies

The developments in the field of biological electron transfer over the past 2 years are reviewed. Attention is given to theoretical developments, especially with respect to the concept of 'electronic pathways' inside proteins, and the association process of redox proteins in solution and the idea of 'conformational gating'.

Refined crystal structure of the 2[4Fe-4S] ferredoxin from Clostridium acidurici at 1.84 A resolution

The crystal structure of the 2[4Fe-4S] ferredoxin from Clostridium acidurici has been determined at a resolution of 1.84 A and refined to an R-factor of 0.169. Crystals belong to space group P4(3)2(1)2 with unit cell dimensions a = b = 34.44 A and c = 74.78 A. The structure was determined by molecular replacement using the previously published model of an homologous ferredoxin and refined by molecular dynamics techniques. The model contains the protein and 46 water molecules. Only two amino acid residues, Asp27 and Asp28, are poorly defined in the electron density maps. The molecule has an overall chain fold similar to that of other [4Fe-4S] bacterial ferredoxins of known structure. The two [4Fe-4S] clusters display similar bond distances and angles. In both of them the co-ordination of one iron atom (bound to Cys11 and Cys40) is slightly distorted as compared with that of the other iron atoms. A core of hydrophobic residues and a few water molecules contribute to the stability of the structure. The [4Fe-4S] clusters interact with the polypeptide chain through eight hydrogen bonds each, in addition to the covalent Fe-Scys bonds. The ferredoxin from Clostridium acidurici is the most typical clostridial ferredoxin crystallized so far and the biological implications of the newly determined structure are discussed.

A "parallel plate" electrostatic model for bimolecular rate constants applied to electron transfer proteins

A "parallel plate" model describing the electrostatic potential energy of protein-protein interactions is presented that provides an analytical representation of the effect of ionic strength on a biomolecular rate constant. The model takes into account the asymmetric distribution of charge on the surface of the protein and localized charges at the site of electron transfer that are modeled as elements of a parallel plate condenser. Both monopolar and dipolar interactions are included. Examples of simple (monophasic) and complex (biphasic) ionic strength dependencies obtained from experiments with several electron transfer protein systems are presented, all of which can be accommodated by the model. The simple cases do not require the use of both monopolar and dipolar terms (i.e., they can be fit well by either alone). The biphasic dependencies can be fit only by using dipolar and monopolar terms of opposite sign, which is physically unreasonable for the molecules considered. Alternatively, the high ionic strength portion of the complex dependencies can be fit using either the monopolar term alone or the complete equation; this assumes a model in which such behavior is a consequence of electron transfer mechanisms involving changes in orientation or site of reaction as the ionic strength is varied. Based on these analyses, we conclude that the principal applications of the model presented here are to provide information about the structural properties of intermediate electron transfer complexes and to quantify comparisons between related proteins or site-specific mutants. We also conclude that the relative contributions of monopolar and dipolar effects to protein electron transfer kinetics cannot be evaluated from experimental data by present approximations.

Circular dichroism studies of the binding of mammalian and non-mammalian cytochromes c to cytochrome c oxidase, cytochrome c peroxidase, and polyanions

The effects of binding of Candida krusei, Drosophila melanogaster, horse, human, and rat cytochromes c to beef cytochrome c oxidase (ferrocytochrome c: oxygen oxidoreductase, EC 1.9.3.1) and yeast cytochrome c peroxidase (ferricytochrome c: hydrogen-peroxide oxidoreductase, EC 1.11.1.5) on their circular dichroism spectra were determined. The binding to cytochrome oxidase results in a positive increase in the ellipticities of the positive and negative Cotton effects at 404 nm and 417 nm of cytochrome c. The horse, human, and rat cytochromes c display less of an increase in the ellipticity of the positive Cotton effect at 404 nm, but more of a positive change in the negative Cotton effect at 417 nm than the C. krusei or D. melanogaster proteins. Interaction with yeast cytochrome c peroxidase elicits only a positive change in the ellipticity of the positive Cotton effect at 404 nm. No significant change is observed in the negative Cotton effect at 417 nm. Rat cytochrome c variants with a phenylalanine in place of tyrosine-67 and/or an alanine in place of proline-30 all display circular dichroism spectral changes upon binding to cytochrome c oxidase or cytochrome c peroxidase identical to those of the unaltered protein. The increase in ellipticity at 404 nm upon binding occurs even though replacement of tyrosine-67 results in the loss of the positive Cotton effect at this position. Polyglutamate and phosvitin complexes of cytochrome c show changes in the circular dichroism spectrum similar to those observed with cytochrome c peroxidase. However, the magnitudes of the spectral changes were considerably less. A model is proposed in which the main cause of the circular dichroism spectral changes observed upon complexation arise from the exclusion of solvent from the exposed front heme edge. According to this model, the exclusion of solvent changes the relative asymmetry of the environment of the electronic transitions of the heme prosthetic group of cytochrome c, resulting in observed circular dichroic effects.

Transient kinetic and oxidation-reduction studies of spinach ferredoxin:nitrite oxidoreductase

The oxidation-reduction midpoint potentials for the two prosthetic groups of the chloroplast-located, ferredoxin-dependent nitrite reductase of spinach leaves have been determined by spectroelectrochemical titrations and cyclic voltammetry. The average of the results obtained by the two techniques are Em = -290 mV for the siroheme group and Em = -365 mV for the [4Fe-4S] cluster. The value obtained for the [4Fe-4S] cluster is substantially more positive than values obtained previously in experiments which utilized electron paramagnetic resonance spectroscopy at cryogenic temperatures to monitor the reduction state of the cluster. Laser flash photolysis experiments have been used to monitor electron transfer from reduced ferredoxin to nitrite reductase and have provided the first evidence for electron transfer between the two prosthetic groups of the enzyme. The effect of ionic strength on the observed kinetics has provided support for the proposal that electrostatic interactions between ferredoxin and nitrite reductase play an important role in the reaction mechanism.

Structure-function studies of [2Fe-2S] ferredoxins

The ability to overexpress [2Fe-2S] ferredoxins in Escherichia coli has opened up exciting research opportunities. High-resolution x-ray structures have been determined for the wild-type ferredoxins produced by the vegatative and heterocyst forms of Anabaena strain 7120 (in their oxidized states), and these have been compared to structural information derived from multidimensional, multinuclear NMR spectroscopy. The electron delocalization in in these proteins in their oxidized and reduced states has been studied by 1H, 2H, 13C, and 15N NMR spectroscopy. Site-directed mutagenesis has been used to prepare variants of these ferredoxins. Mutants (over 50) of the vegetative ferredoxin have been designed to explore questions about cluster assembly and stabilization and to determine which residues are important for recognition and electron transfer to the redox partner Anabaena ferredoxin reductase. The results have shown that serine can replace cysteine at each of the four cluster attachment sites and still support cluster assembly. Electron transfer has been demonstrated with three of the four mutants. Although these mutants are less stable than the wild-type ferredoxin, it has been possible to determine the x-ray structure of one (C49S) and to characterize all four by EPR and NMR. Mutagenesis has identified residues 65 and 94 of the vegetative ferredoxin as crucial to interaction with the reductase. Three-dimensional models have been obtained by x-ray diffraction analysis for several additional mutants: T48S, A50V, E94K (four orders of magnitude less active than wild type in functional assays), and A43S/A45S/T48S/A50N (quadruple mutant).

Protein interaction sites obtained via sequence homology. The site of complexation of electron transfer partners of cytochrome c revealed by mapping amino acid substitutions onto three-dimensional protein surfaces

Amino acid substitutions in all but the most divergent of cytochromes c have been categorized as being conservative or radical and mapped onto the three-dimensional structure of yeast cytochrome c. Color-coded, space-filling representations reveal a large 24 A diameter surface area which is invariant or conservatively substituted on the front left face of the cytochrome c molecule. Chemical modifications and mutations which inhibit complex formation and electron transfer with reaction partners also map to this surface. In sharp contrast, the back side of the protein is randomly substituted with both conservative and radical replacements. The invariant/conservatively substituted surface on the front of cytochrome c thus defines the site of interaction with redox partners and provides a measure of its dimensions. Further, this analysis strongly suggests that there is only a single site of oxidation and reduction on cytochrome c for all of its physiological reactions. The same analysis applied to bacterial cytochrome c2 shows that its conserved surface is similar in size and location to that of cytochrome c. Analyses of native and model reaction partners of cytochromes c and c2, such as cytochrome b5, plastocyanin, and bacterial photosynthetic reaction centers, also reveal probable active site surfaces for complexation and electron transfer, which are complementary in size to that of the c-type cytochromes. The availability of a three-dimensional structure and of several closely related amino acid sequences for a given functional class of protein is the only limitation on this type of analysis, which can then serve as a basis for designing site-directed mutagenesis experiments.

Analysis of the bimolecular reduction of ferricytochrome c by ferrocytochrome b5 through mutagenesis and molecular modelling

Site-directed mutagenesis has been used to produce variants of cytochrome c in which selected structural or functional properties of this protein are altered that have been implicated previously in contributing to the rate at which ferricytochrome c is reduced by ferrocytochrome b5. In total, 18 variants have been studied by kinetics and electrochemical methods to assess the contributions of thermodynamic driving force, surface charge and hydrophobic interactions, and redox-linked structural reorganization of the protein to the rate of electron transfer between these two proteins under conditions where the reaction is bimolecular. While some variants (those at position-38) appear to affect primarily the driving force of the reaction, others appear to influence the rearrangement barrier to electron transfer (those at positions-67 and -52) while the interface between electron donor and acceptor centers is the principal effect of substitutions for a conserved aromatic heme contact residue at the surface of the protein (position-82). Interpretation of these results has been facilitated through the use of energy minimization calculations to refine the hypothetical models previously suggested for the cytochrome c- cytochrome b5 precursor complex on the basis of Brownian dynamics simulations of the bimolecular encounter event.

The cytochrome b5-fold: an adaptable module

The family of b5-like cytochromes encompasses, besides cytochrome b5 itself, hemoprotein domains covalently associated with other redox proteins, in flavocytochrome b2 (L-lactate dehydrogenase), sulfite oxidase and assimilatory nitrate reductase. A comparison of about 40 amino acid sequences deposited in data banks shows that eight residues are invariant and about 15 positions carry strongly conservative substitutions. Examination of the location of these invariant and conserved positions in the light of the three-dimensional structures of beef cytochrome b5 and S cerevisiae flavocytochrome b2 suggests a strongly conserved protein structure for the b5-like heme-binding domain throughout evolution. Numerous NMR studies have demonstrated the existence of a positional isomerism for the heme, which involves both a 180 degree-rotation around the heme alpha,gamma-meso carbon atoms and a rotation through an axis normal to the heme plane at the iron. NMR studies did not detect significant differences in protein structure between reduced and oxidized states, or between species. The role of a number of side chains was probed by site-directed mutagenesis. Studies of complex formation and of electron transfer rates between cytochrome b5 and redox partners have led to the idea that complexation is driven by electrostatic forces, that it is generally the exposed heme edge which makes contact with electron donors and acceptors, but that there are multiple overlapping sites within this general area. For the bi- and trifunctional members of the family, extrapolation of available data would suggest a mobile heme-binding domain within a complex structure. In these cases the existence of a single interaction area for both electron donor and acceptor, or of two different ones, remains open to discussion.

Amino acid residues in Anabaena ferredoxin crucial to interaction with ferredoxin-NADP+ reductase: site-directed mutagenesis and laser flash photolysis

Ferredoxin (Fd) functions in photosynthesis to transfer electrons from photosystem I to ferredoxin-NADP+ reductase (FNR). We have made several site-directed mutants of Anabaena 7120 Fd and have used laser flash photolysis to investigate the effects of these mutations on the kinetics of reduction of oxidized Fd by deazariboflavin semiquinone (dRfH.) and the reduction of oxidized Anabaena FNR by reduced Fd. None of the mutations influenced the second-order rate constant for dRfH. reduction by more than a factor of 2, suggesting that the ability of the [2Fe-2S] cluster to participate in electron transfer was not seriously affected. In contrast, a surface charge reversal mutation, E94K, resulted in a 20,000-fold decrease in the second-order rate constant for electron transfer from Fd to FNR, whereas a similar mutation at an adjacent site, E95K, produced little or no change in reaction rate constant compared to wild-type Fd. Such a dramatic difference between contiguous surface mutations suggests a very precise surface complementarity at the protein-protein interface. Mutations introduced at F65 (F65I and F65A) also decreased the rate constant for the Fd/FNR electron transfer reaction by more than 3 orders of magnitude. Spectroscopic and thermodynamic measurements with both the E94 and F65 mutants indicated that the kinetic differences cannot be ascribed to changes in gross conformation, redox potential, or FNR binding constant but rather reflect the protein-protein interactions that control electron transfer. Several mutations at other sites in the vicinity of E94 and F65 (R42, T48, D68, and D69) resulted in little or no perturbation of the Fd/FNR interaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Intracomplex electron transfer between ruthenium-65-cytochrome b5 and position-82 variants of yeast iso-1-cytochrome c

We tested the idea that the aromatic ring on the invariant residue Phe-82 in cytochrome c acts as an electron-transfer bridge between cytochrome c and cytochrome b5. Ru-65-cyt b5 was prepared by labeling the single sulfhydryl group on T65C cytochrome b5 with [4-(bromomethyl)-4'-methylbipyridine][bis(bipyridine)]ruthenium 2+ as previously described [Willie, A., Stayton, P.S., Sligar, S.G., Durham, B., & Millett, F. (1992) Biochemistry 31, 7237-7242]. Laser excitation of the complex formed between Ru-65-cyt b5 and Saccharomyces cerevisiae iso-1-cytochrome c at low ionic strength results in rapid electron transfer from the excited-state Ru(II*) to the heme group of Ru-65-cyt b5 followed by biphasic electron transfer to the heme group of cytochrome c with rate constants of (1.0 +/- 0.2) x 10(5) s-1 and (2.0 +/- 0.04) x 10(4) s-1. Variants of iso-1-cytochrome c substituted at Phe-82 with Tyr, Gly, Leu, and Ile have fast-phase rate constants of 0.4, 1.9, 2.1, and 2.0 x 10(5) s-1 and slow-phase rate constants of 5.3, 3.5, 2.4, and 2.0 x 10(3) s-1, respectively. Increasing the ionic strength to 50 mM results in single-phase intracomplex electron transfer with rate constants of 3.8, 3.1, 3.0, 5.0, and 4.5 x 10(4) s-1 for the wild-type, Tyr, Gly, Leu, and Ile variants, respectively. These results demonstrate that an aromatic side chain at residue 82 is not needed for rapid electron transfer with cytochrome b5. Furthermore, two conformational forms of the complex are present at low ionic strength with fast and slow electron-transfer rates.(ABSTRACT TRUNCATED AT 250 WORDS)

Transient kinetics of electron transfer from a variety of c-type cytochromes to plastocyanin

Plastocyanin (PC) and its physiological reaction partner cytochrome (cyt) f form a complex which is electrostatically stabilized by interactions between complementary localized charges. We have measured the kinetics of intracomplex electron transfer between several reduced cytochromes and PC using laser flash photolysis. With spinach cyt f and spinach PC, we obtain first-order rate constants, kforward = 2780 s-1 and kreverse = 1050 s-1, for the reversible reaction and a complex dissociation constant of about 23 microM at an ionic strength (I) of 5 mM. The observed rate constant increases by a factor of 2 between I = 5 and 40 mM and then decreases monotonically at higher ionic strengths. This indicates that the complex is not completely dissociated until I = 150 mM and that the proteins within the electrostatically most stable complex are not optimally oriented for electron transfer. Similar results were obtained with turnip cyt f and spinach PC, although in this case intracomplex electron transfer is about 4 times as fast. Horse cyt c also forms an electrostatically stabilized complex with PC, and yields a limiting rate constant for intracomplex electron transfer (1750 s-1) and a dissociation constant (10 microM) comparable to those for spinach cyt f. The ionic strength dependence shows that the complex is more readily dissociated (complete at I = 25 mM) than is that of cyt f and that rearrangement is not required for optimal electron transfer. Addition of polylysine results in 10-fold inhibition of the rate of electron transfer. Pseudomonas cyt c-551 is an acidic cytochrome which does not form a complex with PC.(ABSTRACT TRUNCATED AT 250 WORDS)