The modulation of cytochrome c electron self-exchange by site-specific chemical modification and anion binding

Insights into Interprotein Electron Transfer of Human Cytochrome c Variants Arranged in Multilayer Architectures by Means of an Artificial Silica Nanoparticle Matrix

The redox behavior of proteins plays a crucial part in the design of bioelectronic systems. We have demonstrated several functional systems exploiting the electron exchange properties of the redox protein cytochrome c (cyt c) in combination with enzymes and photoactive proteins. The operation is based on an effective reaction at modified electrodes but also to a large extent on the capability of self-exchange between cyt c molecules in a surface-fixed state. In this context, different variants of human cyt c have been examined here with respect to an altered heterogeneous electron transfer (ET) rate in a monolayer on electrodes as well as an enhanced self-exchange rate while being incorporated in multilayer architectures. For this purpose, mutants of the wild-type (WT) protein have been prepared to change the chemical nature of the surface contact area near the heme edge. The structural integrity of the variants has been verified by NMR and UV-vis measurements. It is shown that the single-point mutations can significantly influence the heterogeneous ET rate at thiol-modified gold electrodes and that electroactive protein/silica nanoparticle multilayers can be constructed with all forms of human cyt c prepared. The kinetic behavior of electron exchange for the mutant proteins in comparison with that of the WT has been found altered in some multilayer arrangements. Higher self-exchange rates have been found for K79A. The results demonstrate that the position of the introduced change in the charge situation of cyt c has a profound influence on the exchange behavior. In addition, the behavior of the cyt c variants in assembled multilayers is found to be rather similar to the situation of cyt c self-exchange in solution verified by NMR.

Electroactive multilayer assemblies of bilirubin oxidase and human cytochrome C mutants: insight in formation and kinetic behavior

Here, we report on cytochrome c/bilirubin oxidase multilayer electrodes with different cytochrome c (cyt c) forms including mutant forms of human cyt c, which exhibit different reaction rates with bilirubin oxidase (BOD) in solution. The multilayer formation via the layer-by-layer technique and the kinetic behavior of the mono (only cyt c) and biprotein (cyt c and BOD) multilayer systems are studied by SPR and cyclic voltammetry. For the layer construction, sulfonated polyaniline is used. The only cyt c containing multilayer electrodes show that the quantity of deposited protein and the kinetic behavior depend on the cyt c form incorporated. In the case of the biprotein multilayer with BOD, it is demonstrated that the catalytic signal chain from the electrode via cyt c to BOD and oxygen can be established with all chosen cyt c forms. However, the magnitude of the catalytic current as well as the kinetic behavior differ significantly. We conclude that the different cytochrome c forms affect three parameters, identified here, to be important for the functionality of the multilayer system: the amount of molecules per layer, which can be immobilized on the electrodes, the cyt c self-exchange rate, and the rate constant for the reaction with BOD.

N epsilon,N epsilon-dimethyl-lysine cytochrome c as an NMR probe for lysine involvement in protein-protein complex formation

The reductively dimethylated derivatives of horse and yeast iso-1-ferricytochromes c have been prepared and characterized for use as NMR probes of the complexes formed by cytochrome c with bovine liver cytochrome b5 and yeast cytochrome c peroxidase. The electrostatic properties and structures of the derivatized cytochromes are not significantly perturbed by the modifications; neither are the electrostatics of protein-protein complex formation or rates of interprotein electron transfer. Two-dimensional 1H-13C NMR spectroscopy of the complexes formed by the derivatized cytochromes with cytochrome b5 and cytochrome c peroxidase has been used to investigate the number and identity of lysine residues of cytochrome c that are involved in interprotein interactions of cytochrome c. The NMR data are incompatible with simple static models proposed previously for the complexes formed by these proteins, but are consistent with the presence of multiple, interconverting complexes of comparable stability, consistent with studies employing Brownian dynamics to model the complexes. The NMR characteristics of the Nepsilon,Nepsilon-dimethyl-lysine groups, their chemical shift dispersion, oxidation state and temperature dependences and the possibility of chemical exchange phenomena are discussed with relevance to the utility of Nepsilon, Nepsilon-dimethyl-lysine's being a generally useful derivative for characterizing protein-protein complexes.

Kinetics of the reduction of wild-type and mutant cytochrome c-550 by methylamine dehydrogenase and amicyanin from Thiobacillus versutus

To elucidate the kinetic properties of the methylamine dehydrogenase (MADH) redox chain of Thiobacillus versutus the reduction of cytochrome c-550 by MADH and amicyanin has been studied. Under steady state conditions, the rate constants of the reactions have been determined as a function of the ionic strength, both for wild type cytochrome c-550 and for mutants in which the conserved residue Lys14 has been replaced as follows: Lys14-->Gln (mutant [K14Q]cytochrome c-550) and Lys14-->Glu (mutant [K14E]cytochrome c-550). The second-order rate constant of the reduction of cytochrome c-550 by MADH shows a biphasic ionic-strength dependence. At low ionic strength the rate constant remains unchanged (wild type) or increases ([K14Q]cytochrome c-550) with increasing ionic strength, while at high salt concentrations the rate constant decreases monotonically as the ionic strength increases. It is suggested that conformational freedom exists in the association complex and that this is favourable for electron transfer. [K14Q]cytochrome c-550 and [K14E]cytochrome c-550 are reduced at rates 20-fold and 500-fold slower than wild-type cytochrome c-550 by MADH, due to a lower association constant. It is concluded that MADH possesses a negative patch with which cytochrome c-550 associates. Lys14 plays an important role in the formation of the reaction complex. The midpoint potentials of wild-type and mutant cytochrome c-550 have been determined by using cyclic voltammetry. [K14Q]cytochrome c-550 and [K14E]cytochrome c-550 show an increase in E0 of only 2 mV and 8 mV, respectively, compared to wild-type cytochrome c-550 (241 mV at pH 8.1). [K14Q]cytochrome c-550 and [K14E]cytochrome c-550 cytochrome c-550 are reduced by amicyanin at rates that are only slightly faster than for wild-type cytochrome c-550. The difference is partly attributable to the change in E0. High ionic strength results in a threefold increase in the rate in all three cases. These results indicate that charge interactions do not play a major role in the formation of the amicyanin/cytochrome c-550 reaction complex, suggesting an interaction at the hydrophobic patch of amicyanin. The reduction of cytochrome c-550 by MADH can be inhibited by Zn(2+)-substituted amicyanin. Ag(+)-amicyanin, however, has little effect on the reduction rate. These results suggest that MADH has a much higher affinity for Cu(2+)-amicyanin (substrate) than for Cu(+)-amicyanin (product). On the basis of these findings the roles of the components of the MADH redox chain are discussed.

Mutagenesis of the conserved lysine 14 of cytochrome c-550 from Thiobacillus versutus affects the protein structure and the electron self-exchange rate

The lysine residue K14 of cytochrome c-550 of Thiobacillus versutus has been mutated to a glutamine (Q) and a glutamate (E) residue. These mutations have a minimal effect on the pKa for replacement of the methionine ligand (the "alkaline transition"), indicating that a presumptive salt bridge between K14 and E11 does not help stabilize the native form. This is in contrast with mitochondrial cytochrome c, where the homologous K13 forms a structurally important salt bridge with glutamate 90. The NMR signals of protons close to the heme iron in wild-type and mutant ferricytochrome c-550 shift considerably with increasing ionic strength. These effects resemble those seen in mitochondrial cytochrome c upon addition of salt and upon complex formation with redox partners. It is likely that electrostatic screening of positive charges near the heme crevice leads to a slight redistribution of the electron density in the heme. At low ionic strength the NMR spectrum of wild-type cytochrome c-550 shows broad peaks. Line widths decrease upon addition of salt up to 200 mM. In K14Q and K14E cytochrome c-550 the line widths are much smaller at low ionic strength. Wild-type cytochrome c-550 may exist in two exchanging conformations, one of which may represent a more open (non-native) form, in analogy with cytochrome c. However, in the case of cytochrome c-550 this non-native form does not show ligand replacement. The electron self-exchange rates of wild type and mutants have been determined as a function of the ionic strength.(ABSTRACT TRUNCATED AT 250 WORDS)

The identification of cation-binding domains on the surface of microsomal cytochrome b5 using 1H-NMR paramagnetic difference spectroscopy

One-dimensional and two-dimensional 1H-NMR methods and paramagnetic difference spectroscopy have defined cation binding domains on the surface of the tryptic fragment of microsomal cytochrome b5. The addition of tris(ethylenediamine) chromium(III) [Cr(en)3(3+)] to solutions of ferricytochrome b5 reveals at least three distinct sites on the surface of the protein to which highly charged cations may bind (20 mM phosphate pH 7.0, T = 300 K). Surprisingly only one of these sites is located close to the haem edge region of the protein, whilst the remaining two sites are more remote. Site I contains the exposed haem C13 propionate and a series of carboxylate residues that includes glutamates 37, 38, 43, 44, and 48. Sites II and III are located away from the haem edge region and are delineated by the broadening of aromatic resonances of histidines 26 and 80. Further investigation of the interaction between Cr(en)3(3+) and cytochrome b5 using two-dimensional double-quantum-filtered correlated spectroscopy shows that resonances assigned to Glu59, Asp60, Glu79, Asp82 and Asp83 are broadened with the distribution of these charged side chains correlating with the relaxation broadening observed from one-dimensional experiments. In a binary complex with ferricytochrome c, Cr(en3(3+) broadens many cytochrome b45 resonances including the haem propionates, His26, Ala54, Thr55 and His80. Although the pattern of line-broadening of resonances at sites II and III is unaltered by complex formation, cytochrome c shields residues at site I, the haem edge site. The results indicate that the interaction between cytochrome b5 and c in a binary complex involves multiple protein configurations.

The promotion of self-association of horse-heart cytochrome c by hexametaphosphate anions

In the presence of the highly charged hexametaphosphate anion, horse heart cytochrome c aggregates to form stable protein complexes. The formation of protein aggregates has been detected by high-resolution 1H-NMR spectroscopy from an increase in the linewidth of resolved ferricytochrome c resonances with hexametaphosphate concentration. Alternatively, analytical ultracentrifugation reveals protein association from the increase in apparent sedimentation coefficients of cytochrome c in the presence of equimolar hexametaphosphate. Protein aggregation is dependent on the concentration of background electrolyte since in the range 10-150 mM sodium cacodylate alternative stabilisation of dimeric and trimeric complexes was observed by both NMR and analytical ultracentrifugation. A model is proposed for the mechanism of protein aggregation caused by polyphosphate binding to the surface of cytochrome c.

Characterisation of the electron self-exchange rates in hexametaphosphate-cytochrome-c aggregates measured using high-resolution 1H-NMR spectroscopy

1H-NMR spectroscopy has been used to measure the rate of unimolecular electron exchange between cytochrome c molecules in protein aggregates stabilised by the addition of sodium hexametaphosphate. The average intracomplex electron exchange rate is measured from line broadening of hyperfine-shifted resonances of ferricytochrome c in an equimolar mixture of reduced and oxidised protein. The line-broadening due to electron exchange is significantly greater than that due to protein aggregation and reaches a maximum value between 1-2 mol hexametaphosphate/mol protein. Significantly the exchange-induced broadening is a first-order process and is directly proportional to the size of the cytochrome c oligomer. From the temperature dependence of exchange broadening the activation enthalpy was estimated to be 75.8 kJ mol-1 whereas the activation entropy was 295 J mol-1 K-1 for a dimer of cytochrome c at a hexametaphosphate/protein molar ratio of 1. Both activation parameters decrease in magnitude as the order of the cytochrome c oligomer increases. The rates of intracomplex electron exchange in Saccharomyces cerevisiae iso-2 and Candida krusei cytochromes c are lower than that of the horse protein, implying that primary sequence plays a fundamental part in determining the rate of exchange. The relevance of these observations is discussed in terms of the function of cytochrome c.

The location of the polyphosphate-binding sites on cytochrome c measured by NMR paramagnetic difference spectroscopy

Analyses of unimolecular electron self-exchange reactions provide a comparatively simple and direct approach to understanding biological electron transfer. Such studies are currently limited by a lack of well characterised aggregating systems. In the presence of sodium hexametaphosphate, cytochrome c forms stable protein aggregates as a result of binding hexametaphosphate at a single site on its surface (preceding paper in this issue of the journal). Here we report the location of the principal polyphosphate binding site on the surface of cytochrome c for both hexametaphosphate and a second polyphosphate, tripolyphosphate determined using 1H-NMR spectroscopy in conjunction with the relaxation probe potassium hexacyanochromium(III). Addition of either hexametaphosphate or tripolyphosphate to ferricytochrome c in the presence of the relaxation probe causes a decrease in intensity of several resonances in the paramagnetic difference spectrum, including Phe82 ortho/meta, Ile85 delta methyl and Ile9 gamma methyl. Together these effects put the site of polyphosphate binding close to lysines 13, 86, and 87. Additionally the effect of sodium tripolyphosphate and sodium trimetaphosphate on cytochrome c aggregation is described. The potential role of this site in anion-induced cytochrome c aggregation is discussed.

High-resolution three-dimensional structure of horse heart cytochrome c

The 1.94 A resolution three-dimensional structure of oxidized horse heart cytochrome c has been elucidated and refined to a final R-factor of 0.17. This has allowed for a detailed assessment of the structural features of this protein, including the presence of secondary structure, hydrogen-bonding patterns and heme geometry. A comprehensive analysis of the structural differences between horse heart cytochrome c and those other eukaryotic cytochromes c for which high-resolution structures are available (yeast iso-1, tuna, rice) has also been completed. Significant conformational differences between these proteins occur in three regions and primarily involve residues 22 to 27, 41 to 43 and 56 to 57. The first of these variable regions is part of a surface beta-loop, whilst the latter two are located together adjacent to the heme group. This study also demonstrates that, in horse cytochrome c, the side-chain of Phe82 is positioned in a co-planar fashion next to the heme in a conformation comparable to that found in other cytochromes c. The positioning of this residue does not therefore appear to be oxidation-state-dependent. In total, five water molecules occupy conserved positions in the structures of horse heart, yeast iso-1, tuna and rice cytochromes c. Three of these are on the surface of the protein, serving to stabilize local polypeptide chain conformations. The remaining two are internally located. One of these mediates a charged interaction between the invariant residue Arg38 and a nearby heme propionate. The other is more centrally buried near the heme iron atom and is hydrogen bonded to the conserved residues Asn52, Tyr67 and Thr78. It is shown that this latter water molecule shifts in a consistent manner upon change in oxidation state if cytochrome c structures from various sources are compared. The conservation of this structural feature and its close proximity to the heme iron atom strongly implicate this internal water molecule as having a functional role in the mechanism of action of cytochrome c.

Electrostatic and steric control of electron self-exchange in cytochromes c, c551, and b5

The ionic strength dependence of the electron self-exchange rate constants of cytochromes c, c551, and b5 has been analyzed in terms of a monopole-dipole formalism (van Leeuwen, J.W. 1983. Biochim. Biophys. Acta. 743:408-421). The dipole moments of the reduced and oxidized forms of Ps. aeruginosa cytochrome c551 are 190 and 210 D, respectively (calculated from the crystal structure). The projections of these on the vector from the center of mass through the exposed heme edge are 120 and 150 D. For cytochrome b5, the dipole moments calculated from the crystal structure are 500 and 460 D for the reduced and oxidized protein; the projections of these dipole moments through the exposed heme edge are -330 and -280 D. A fit of the ionic strength dependence of the electron self-exchange rate constants gives -280 (reduced) and -250 (oxidized) D for the center of mass to heme edge vector. The self-exchange rate constants extrapolated to infinite ionic strength of cytochrome c, c551, and b5 are 5.1 x 10(5), 2 x 10(7), and 3.7 x 10(5) M-1 s-1, respectively. The extension of the monopole-dipole approach to other cytochrome-cytochrome electron transfer reactions is discussed. The control of electron transfer by the size and shape of the protein is investigated using a model which accounts for the distance of the heme from each of the surface atoms of the protein. These calculations indicate that the difference between the electrostatically corrected self-exchange rate constants of cytochromes c and c551 is due only in part to the different sizes and heme exposures of the two proteins.

Electrostatic interactions of 4-carboxy-2,6-dinitrophenyllysine-modified cytochromes c with physiological and non-physiological redox partners

An analysis of the effect of electrostatic properties of 4-carboxy-2,6-dinitrophenyllysine (CDNP-lysine) cytochromes c on their reactions with strongly and weakly binding redox partners is given. For strongly binding systems (cytochrome-c oxidase, cytochrome-c reductase, sulphite oxidase and yeast cytochrome-c peroxidase) the magnitude of the dipole moments of the CDNP cytochromes c determines their relative reactivities. For weakly binding redox agents, such as hexacyanoferrate(III), cobalt(III)tris(1,10-phenanthroline), azurin and plastocyanin, the electrostatic potential at the haem edge accounts for the greater part of the relative activities. Relative rate data were obtained from the literature. It is concluded that the dipole moment of native cytochromes c may account for an approx. 50-fold increase in the efficiency of its physiological activity towards membrane-bound enzymes. A correction on a formula to describe the contribution of a molecular dipole moment to the ionic strength dependence of a bimolecular rate constant (Koppenol, W. H. (1980) Biophys. J. 29, 493-508) leads to an equation nearly identical to that obtained by Van Leeuwen et al. (Van Leeuwen, J.W., Mofers, F.J.M. and Verrman, E.C.I. (1981) Biochim. Biophys. Acta 635, 434-439).

Direct and indirect electron transfer between electrodes and redox proteins

The direct electrochemistry of redox proteins has been achieved at a variety of electrodes, including modified gold, pyrolytic graphite and metal oxides. Careful design of electrode surfaces and electrolyte conditions are required for the attainment of rapid and reversible protein-electrode interaction. The electron transfer reactions of more complex systems, such as redox enzymes, are now being examined. The 'well-behaved' electrochemistry of redox proteins can be usefully exploited by coupling the electrode reaction to enzymes for which the redox proteins act as cofactors. In systems where direct electron transfer is very slow, small electron carriers, or mediators, may be employed to enhance the rate of electron exchange with the electrode. The organometallic compound ferrocene and its derivatives have proved particularly effective in this role. A new generation of electrochemical biosensors employs ferrocene derivatives as mediators.