Site-specific mutagenesis demonstrates that the structural requirements for efficient electron transfer in Anabaena ferredoxin and flavodoxin are highly dependent on the reaction partner: kinetic studies with photosystem I, ferredoxin:NADP+ reductase, and cytochrome c.

Electron transfer reactions involving site-specific mutants of Anabaena ferredoxin (Fd) and flavodoxin (Fld) modified at surface residues close to the prosthetic groups, with photoexcited P700 in spinach photosystem I (PSI) particles, ferredoxin:NADP+ reductase (FNR), and horse cytochrome c (cytc), have been investigated by laser flash photolysis and stopped-flow spectrophotometry. Nonconservative mutations in Fd at F65 and E94, which have been shown to result in very large inhibitions of electron transfer to FNR, were found to yield wild-type behavior in reactions with PSI and cytc. In general, the effects of Fd mutagenesis on the PSI reactions were considerably smaller than those observed for the FNR reaction.

Comparison of electron transfer kinetics between redox proteins free in solution and electrostatically complexed to a lipid bilayer membrane.

The second-order rate constants obtained in solution for the reduction of horse cytochrome c (cytc; net charge +7) by either Clostridium beijerinckii flavodoxin semiquinone (Fld; net charge -16) or reduced spinach ferredoxin (Fd; net charge -15) decrease monotonically with increasing ionic strength, as expected for reactions between oppositely charged species. Although the rate constant for the Fld reaction is almost two orders of magnitude larger at low ionic strength than that for Fd, the values extrapolated to infinite ionic strength are closely similar, indicating comparable reactivities when electrostatic effects are eliminated. Furthermore, Fld has a much larger value for the electrostatic interaction energy, and thus a larger apparent active site charge, than does Fd, accounting for the rate constant disparity at low ionic strength.

Electrostatic modulation of the kinetics of electron transfer from cytochrome c to cobalt phenanthroline by binding to lipid bilayers: effects of ionic strength and extent of incorporation of various negatively charged lipids.

The effect of electrostatically binding ferrous cytochrome c to anionic liposomes, composed of dimyristoyl phosphatidylglycerol (DMPG-), dioleoyl phosphatidyl-glycerol (DOPG-), or cardiolipin (CL2-) mixed with varying amounts of egg phosphatidylcholine (PC), on the kinetics of cytochrome oxidation by the positively charged cobalt phenanthroline ion has been measured using stopped-flow spectrophotometry. The rate of electron transfer is enhanced as much as 3000-fold by increasing the number of negatively charged binding sites on the liposome surface, and by as much as 1000-fold by decreasing the ionic strength of the buffer. The sigmoidal shape of the curve of rate constant vs mole percent anionic lipid is consistent with a positively cooperative effect of the negative surface charge.

Electrostatic effects on the kinetics of electron transfer reactions of cytochrome c caused by binding to negatively charged lipid bilayer vesicles.

The effect of binding reduced tuna mitochondrial cytochrome c to negatively charged lipid bilayer vesicles at low ionic strength on the kinetics of electron transfer to various oxidants was studied by stopped-flow spectrophotometry. Binding strongly stimulated (up to 100-fold) the rate of reaction with the positively charged cobalt phenanthroline ion, whereas the rate of reaction with the negatively charged ferricyanide ion was greatly inhibited (up to 60-fold), as compared with the same systems either at high ionic strength or at low ionic strength either in the presence of electrically neutral vesicles or in the absence of vesicles. Reactions of tuna cytochrome c with uncharged or electrically neutral oxidants such as benzoquinone and Rhodospirillum rubrum cytochrome c2 were unaffected by binding to vesicles, suggesting little or no effect of membrane association on cytochrome structure or accessibility of the heme center.

Electrostatic effects on the spectral and redox properties of Clostridium pasteurianum flavodoxin: effects of salt concentration and polylysine.

When polylysine is complexed to flavodoxin at low ionic strength, the electrostatic potential of the region which is involved in electron transfer is modified such that positively charged oxidants react more slowly with flavodoxin semiquinone, and negatively charged oxidants react more rapidly. The reaction rate of the uncharged benzoquinone molecule is unaffected. An especially strong effect (approximately 200-fold) occurs with ferricyanide.

Redox protein electron-transfer mechanisms: electrostatic interactions as a determinant of reaction site in c-type cytochromes.

The effect of ionic strength on the rate constant for electron transfer has been used to determine the magnitude and charge sign of the net electrostatic potential which exists in close proximity to the sites of electron transfer on various c-type cytochromes. The negatively charged ferricyanide ion preferentially reacts at the positively charged exposed heme edge region on the front side of horse cytochrome c and Paracoccus cytochrome c2. In contrast, at low ionic strength, the positively charged cobalt phenanthroline ion interacts with the negatively charged back side of cytochrome c2, and at high ionic strength at a positively charged site on the front side of the cytochrome.

Laser flash photolysis studies of the kinetics of reduction of spinach and Clostridium ferredoxins by a viologen analogue: electrostatically controlled nonproductive complex formation and differential reactivity among the iron-sulfur clusters.

We have studied the transient kinetics of electron transfer from a positively charged viologen analogue (propylene diquat), reduced by pulsed laser excitation of the deazariboflavin/EDTA system, to the net negatively charged ferredoxins from spinach and Clostridium pasteurianum. Spinach ferredoxin showed monophasic kinetics over the ionic strength range studied, consistent with the presence of only a single iron-sulfur center. Clostridium ferredoxin at low ionic strength showed biphasic kinetics, which indicates a differential reactivity of the two iron-sulfur centers of this molecule toward the electron donor.

Electron-transfer reactions between flavodoxin semiquinone and c-type cytochromes: comparisons between various flavodoxins.

As an extension of previous work from this laboratory using Clostridium pasteurianum flavodoxin [Tollin, G., Cheddar, G., Watkins, J.

Transient kinetics of reduction of blue copper proteins by free flavin and flavodoxin semiquinones.

Rate constants have been determined for the electron-transfer reactions between reduced free flavins and flavodoxin semiquinone and several blue copper proteins. Correlations between these values and redox potentials demonstrate that spinach plastocyanin, Pseudomonas aeruginosa azurin, Alcaligenes sp. azurin, and Alcaligenes sp.

Kinetics of electron transfer between cytochromes c' and the semiquinones of free flavin and clostridial flavodoxin.

Rate constants have been measured for the reactions of a series of high-spin cytochromes c' and their low-spin homologues (cytochromes c-554 and c-556) with the semiquinones of free flavins and flavodoxin. These cytochromes are approximately 3 times more reactive with lumiflavin and riboflavin semiquinones than are the c-type cytochromes that are homologous to mitochondrial cytochrome c. We attribute this to the greater solvent exposure of the heme in the c'-type cytochromes.

Kinetics of reduction of high redox potential ferredoxins by the semiquinones of Clostridium pasteurianum flavodoxin and exogenous flavin mononucleotide. Electrostatic and redox potential effects.

We have measured the ionic strength dependence of the rate constants for the electron-transfer reactions of flavin mononucleotide (FMN) and flavodoxin semiquinones with 10 high redox potential ferredoxins (HiPIP's). The rate constants were extrapolated to infinite ionic strength by using a theoretical model of electrostatic interactions developed in our laboratory. In all cases, the sign of the electrostatic interaction was the same as the protein net charge, but the magnitudes were much smaller.

Electron transfer between flavodoxin semiquinone and c-type cytochromes: correlations between electrostatically corrected rate constants, redox potentials, and surface topologies.

We have measured the ionic strength dependence of the rate constants for electron transfer from the semiquinone of Clostridium pasteurianum flavodoxin to 12 c-type cytochromes and several inorganic oxidants using stopped-flow methodology. The experimental data were fit quite well by an electrostatic model that represents the interaction domains as parallel disks with a point charge equal to the charge within this region of the protein. The analysis provides an evaluation of the electrostatic interaction energy and the rate constant at infinite ionic strength (k affinity).