Reversible electrochemistry of fumarate reductase immobilized on an electrode surface. Direct voltammetric observations of redox centers and their participation in rapid catalytic electron transport.

Fumarate reductase (Escherichia coli) can be immobilized in an extremely electroactive state at an electrode, with retention of native catalytic properties. The membrane-extrinsic FrdAB component adsorbs to monolayer coverage at edge-oriented pyrolytic graphite and catalyzes reduction of fumarate or oxidation of succinate, depending upon the electrode potential. In the absence of substrates, reversible redox transformations of centers in the enzyme are observed by cyclic voltammetry. The major component of the voltammograms is a pair of narrow reduction and oxidation signals corresponding to a pH-sensitive couple with formal reduction potential E degree' = -48 mV vs SHE at pH 7.0 (25 degrees C). This is assigned to two-electron reduction and oxidation of the active-site FAD. A redox couple with E degree' = -311 mV at pH 7 is assigned to center 2 ([4Fe-4S]2+/1+). Voltammograms for fumarate reduction at 25 degrees C, measured with a rotating-disk electrode, show high catalytic activity without the low-potential switch-off that is observed for the related enzyme succinate dehydrogenase. The catalytic electrochemistry is interpreted in terms of a basic model incorporating mass transport of substrate, interfacial electron transfer, and intrinsic kinetic properties of the enzyme, each of these becoming a rate-determining factor under certain conditions. Electrochemical reversibility is approached under conditions of low turnover rate, for example, as the supply of substrate to the active site is limited. In this situation, electrocatalytic half-wave potentials, E1/2, are similar for oxidation of bulk succinate and reduction of bulk fumarate and coincide closely with the E degree' value assigned to the FAD. At 25 degrees C and pH 7, the apparent KM for fumarate reduction is 0.16 mM, and kcat is 840 s-1. Accordingly the second-order rate constant, kcat/KM, is 5.3 x 10(6) M-1 s-1. Under the same conditions, oxidation of succinate is much slower. As the supply of fumarate to the enzyme is raised to increase turnover, the electrochemical reaction eventually becomes limited by the rate of electron transfer from the electrode. Under these conditions a second catalytic wave becomes evident, the E1/2 value of which corresponds to the reduction potential of the redox couple suggested to be center 2. This small boost to the catalytic current indicates that the low-potential [4Fe-4S] cluster can function as a second center for relaying electrons to the FAD.

[1]  M. Johnson,et al.  Magnetic circular dichroism studies of succinate dehydrogenase. Evidence for [2Fe-2S], [3Fe-xS], and [4Fe-4S] centers in reconstitutively active enzyme. , 1985, The Journal of biological chemistry.

[2]  G. Cecchini,et al.  Interactions of oxaloacetate with Escherichia coli fumarate reductase. , 1989, Archives of biochemistry and biophysics.

[3]  B. Chance,et al.  Cytochrome Systems: Molecular Biology and Bioenergetics , 1988 .

[4]  S. Cole,et al.  A mutant of Escherichia coli fumarate reductase decoupled from electron transport. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[5]  J. Heyrovský Principles of polarography , 1966 .

[6]  F. Armstrong,et al.  Evidence for reversible multiple redox transformations of [3Fe‐4S] clusters , 1989 .

[7]  Ralph N. Adams,et al.  Electrochemistry at Solid Electrodes , 1969 .

[8]  J. Weiner,et al.  [36] Fumarate reductase of Escherichia coli☆ , 1986 .

[9]  R. Gunsalus,et al.  Fumarate reductase mutants of Escherichia coli that lack covalently bound flavin. , 1989, The Journal of biological chemistry.

[10]  T. Ohnishi Structure of the Succinate-Ubiquinone Oxidoreductase (Complex II) , 1987 .

[11]  F. Armstrong,et al.  Diode-like behaviour of a mitochondrial electron-transport enzyme , 1992, Nature.

[12]  F. Armstrong,et al.  Binding of thallium(I) to a [3Fe-4S] cluster: evidence for rapid and reversible formation of [Tl3Fe-4S]2+ and [Tl3Fe-4S]1+ centers in a ferredoxin , 1991 .

[13]  J. Bowyer,et al.  Thermodynamic and electron paramagnetic resonance characterization of flavin in succinate dehydrogenase. , 1981, The Journal of biological chemistry.

[14]  R. Gunsalus,et al.  Evidence for non‐cysteinyl coordination of the [2Fe‐2S] cluster in Escherichia coli succinate dehydrogenase , 1992, FEBS letters.

[15]  J. Weiner,et al.  Purification and characterization of membrane-bound fumarate reductase from anaerobically grown Escherichia coli. , 1979, Canadian Journal of Biochemistry.

[16]  F. Armstrong,et al.  Fast interfacial electron transfer between cytochrome c peroxidase and graphite electrodes promoted by aminoglycosides: novel electroenzymic catalysis of hydrogen peroxide reduction , 1987 .

[17]  W. R. Frisell,et al.  Purification and characterization of the flavin prosthetic group of sarcosine dehydrogenase. , 1972, Archives of biochemistry and biophysics.

[18]  F. Mȕller Chemistry and Biochemistry of Flavoenzymes: Volume I , 1991 .

[19]  J. Weiner,et al.  Evidence that centre 2 in Escherichia coli fumarate reductase is a [4Fe-4S]cluster. , 1986, Biochimica et biophysica acta.

[20]  J. Weiner,et al.  Fumarate reductase of Escherichia coli. Elucidation of the covalent-flavin component. , 1979, The Journal of biological chemistry.

[21]  P. Stephens,et al.  Site-directed mutagenesis of Azotobacter vinelandii ferredoxin I. Changes in [4Fe-4S] cluster reduction potential and reactivity. , 1991, The Journal of biological chemistry.

[22]  F. Armstrong,et al.  Electrochemical and spectroscopic characterization of the 7Fe form of ferredoxin III from Desulfovibrio africanus. , 1989, The Biochemical journal.

[23]  R. S. Nicholson,et al.  Theory of Stationary Electrode Polarography. Single Scan and Cyclic Methods Applied to Reversible, Irreversible, and Kinetic Systems. , 1964 .

[24]  R. Gunsalus,et al.  [3Fe-4S] to [4Fe-4S] cluster conversion in Escherichia coli fumarate reductase by site-directed mutagenesis. , 1992, Biochemistry.

[25]  E. Laviron The use of linear potential sweep voltammetry and of a.c. voltammetry for the study of the surface electrochemical reaction of strongly adsorbed systems and of redox modified electrodes , 1979 .

[26]  F. Armstrong,et al.  Investigation of metal ion uptake reactivities of [3Fe-4S] clusters in proteins : voltammetry of co-adsorbed ferredoxin-aminocyclitol films at graphite electrodes and spectroscopic identification of transformed clusters , 1991 .

[27]  H. Beinert,et al.  Interrelations of reconstitution activity, reactions with electron acceptors, and iron-sulfur centers in succinate dehydrogenase. , 1977, Archives of biochemistry and biophysics.

[28]  F. Armstrong,et al.  Probing metalloproteins by voltammetry , 1990 .

[29]  E. Laviron General expression of the linear potential sweep voltammogram in the case of diffusionless electrochemical systems , 1979 .

[30]  R. Gunsalus,et al.  Site-directed mutagenesis of conserved cysteine residues in Escherichia coli fumarate reductase: modification of the spectroscopic and electrochemical properties of the [2Fe-2S] cluster. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[31]  S. Cole,et al.  Molecular biology, biochemistry and bioenergetics of fumarate reductase, a complex membrane-bound iron-sulfur flavoenzyme of Escherichia coli. , 1985, Biochimica et biophysica acta.

[32]  R. Gunsalus,et al.  Identification of active site residues of Escherichia coli fumarate reductase by site-directed mutagenesis. , 1991, The Journal of biological chemistry.

[33]  J. Maguire,et al.  MECHANISMS OF ELECTRON TRANSFER IN SUCCINATE DEHYDROGENASE AND FUMARATE REDUCTASE: POSSIBLE FUNCTIONS FOR IRON-SULPHUR CENTRE 2 AND CYTOCHROME b , 1987 .