Metalloprotein complexes for the study of electron-transfer reactions. Characterization of diprotein complexes obtained by covalent cross-linking of cytochrome c and plastocyanin with a carbodiimide.

Cytochrome c (cyt) and zinc cytochrome c (Zncyt) are separately cross-linked to plastocyanin (pc) by the carbodiimide EDC according to a published method. The changes in the protein reduction potentials indicate the presence of approximately two amide cross-links. Chromatography of the diprotein complexes cyt/pc and Zncyt/pc on CM-52 resin yields multiple fractions, whose numbers depend on the eluent. UV-vis, EPR, CD, MCD, resonance Raman, and surface-enhanced resonance Raman spectra show that cross-linking does not significantly perturb the heme and blue copper active sites. Degrees of heme exposure show that plastocyanin covers most of the accessible heme edge in cytochrome c. Impossibility of cross-linking cytochrome c to a plastocyanin derivative whose acidic patch had been blocked by chemical modification shows that it is the acidic patch that abuts the heme edge in the covalent complex. The chromatographic fractions of the covalent diprotein complex are structurally similar to one another and to the electrostatic diprotein complex. Isoelectric points show that the fractions differ from one another in the number and distribution of N-acylurea groups, byproducts of the reaction with the carbodiimide. Cytochrome c and plastocyanin are also tethered to each other via lysine residues by N-hydroxysuccinimide diesters. Tethers, unlike direct amide bonds, allow mobility of the cross-linked molecules. Laser-flash-photolysis experiments show that, nonetheless, the intracomplex electron-transfer reaction cyt(II)/pc(II)----cyt(III)/pc(I) is undetectable in complexes of either type. Only the electrostatic diprotein complex, in which protein rearrangement from the docking configuration to the reactive configuration is unrestricted, undergoes this intracomplex reaction at a measurable rate.

Unimolecular and bimolecular oxidoreduction reactions involving diprotein complexes of cytochrome c and plastocyanin. Dependence of electron-transfer reactivity on charge and orientation of the docked metalloproteins.

Cytochrome c and plastocyanin form an electrostatic complex, which can be reinforced by amide bonds in the presence of a carbodiimide. Besides this cross-linking, carbodiimide also converts carboxylate side chains into neutral N-acylurea groups. Four derivatives of the covalent diprotein complex, which differ in the degree of this charge neutralization, are separated by cation-exchange chromatography. Electron-transfer reactions at different ionic strengths involving the electrostatic complex and the four derivatives of the covalent complex are studied by laser flash photolysis with flavin semiquinones as reducing agents. The reactivity of the associated proteins toward external reductants cannot be predicted simply on the basis of this reactivity of the separate proteins. Qualitative analysis of the dependence on ionic strength of the reactions between FMN semiquinone and the covalent derivatives indicates sites at which this reductant interacts with the cross-linked proteins. The surprisingly small steric shielding of the protein redox sites in the covalent complex, as deduced from the reactions at high ionic strength, may indicate that the proteins have multiple reaction domains on their surfaces or that the complex is dynamical or both. The intracomplex (unimolecular) electron-transfer reaction is fast in the electrostatic complex (ket = 1300 +/- 200 s-1) but undetectably slow in each of the four derivatives of the covalent complex (ket less than 0.2 s-1).(ABSTRACT TRUNCATED AT 250 WORDS)

Oxidoreduction reactions involving the electrostatic and the covalent complex of cytochrome c and plastocyanin: importance of the protein rearrangement for the intracomplex electron-transfer reaction.

Horse heart cytochrome c and French bean plastocyanin are cross-linked one-to-one by a carbodiimide [Geren, L. M., Stonehuerner, J., Davis, D. J., & Millett, F. (1983) Biochim. Biophys. Acta 724, 62] in the same general orientation in which they associate electrostatically [King, G. C., Binstead, R. A., & Wright, P. E. (1985) Biochim. Biophys. Acta 806, 262]. The reduction potentials of the Fe and Cu atoms in the covalent diprotein complex are respectively 245 and 385 mV vs NHE; the EPR spectra of the two metals are not perturbed by cross-linking. Four isomers of the covalent diprotein complex, which probably differ slightly from one another in the manner of cross-linking, are separated efficiently by cation-exchange chromatography. Stopped-flow spectrophotometric experiments with the covalent diprotein complex show that the presence of plastocyanin somewhat inhibits oxidation of ferrocytochrome c by [Fe(CN)6]3- and somewhat promotes oxidation of this protein by [Fe(C5H5)2]+. These changes in reactivity are explained in terms of electrostatic and steric effects. Pulse-radiolysis experiments with the electrostatic diprotein complex yield association constants of greater than or equal to 5 X 10(6) and 1 X 10(5) M-1 at ionic strengths of 1 and 40 mM, respectively, and the rate constant of 1.05 X 10(3) s-1, regardless of the ionic strength, for the intracomplex electron-transfer reaction. Analogous pulse-radiolysis experiments with each of the four isomers of the covalent diprotein complex, at ionic strengths of both 2 and 200 mM, show an absence of the intracomplex electron-transfer reaction. A rearrangement of the proteins for this reaction seems to be possible (or unnecessary) in the electrostatic complex but impossible in the covalent complex.