The concerted reduction of the high- and low-potential chains of the bf complex by plastoquinol

Abstract We have measured the equilibrium constant for the reaction by which the plastoquinol: plastocyanin oxidoreductase (bf complex) oxidizes plastoquinol. By destroying or removing plastocyanin from spinach thylakoids, the terminal electron acceptor for oxidation of plastoquinol was changed from the oxidized primary donor of Photosystem I (P700+) to oxidized cytochrome f (cyt f+). Because cytochrome f has a lower mid-point redox potential than P700, the equilibrium constant for oxidation of plastoquinol was lowered by this treatment. Chloroplasts were poised at high ambient redox potential (Eh) (about + 450 mV), to oxidize the cytochromes of the bf complex, and then excited by actinic flashes so that Photosystem II (PS II) produced excess PQH2. After such treatment, cytochromes b and f became partially reduced following flash excitation. Cytochrome f reduction occurred in two distinct phases: a rapid phase with t 1 2 = about 6–10 ms , and a slow phase with t 1 2 > 100 ms . The rapid reduction phase corresponded well in kinetics and extent to the rapid reduction phase of cytochrome b (cyt b). The slow phase of cyt f reduction was linked to re-oxidation of cyt b, with complex kinetics. From these results, and estimation of the concentration of plastoquinone (PQ) and plastoquinol (PQH2), we conclude that the concerted reduction of cyt b and f by PQH2 at the PQH2 oxidizing site (Qo-site) reached its local thermodynamic equilibrium at the end of the fast phase of cyt f reduction. At this point, there was not sufficient driving force in the PQ/PQH2 couple to further reduce both cyt f and cyt b, and cyt f reduction could occur only as cyt b became re-oxidized through the PQ-reductase site of the bf complex. From these data, we estimate that, at pH 7.3, the equilibrium constant for the concerted reduction of cyt b and cyt f by the PQ pool was approx. 10, which is consistent with the equilibrium constant calculated from measured values for the midpoint potentials of the redox components. By repeating these experiments at different values of pH, we have shown that the equilibrium constant is pH dependent, and follows the value expected from the measured pH-dependencies of midpoint potentials for the redox components. Our hypothesis is further supported by experiments in which, upon addition of MOA-stilbene, the re-oxidation of cyt b was strongly inhibited and the slow phase of cyt f reduction was greatly slowed, and in which, upon addition of benzoquinone (BQ), the rates of re-oxidation of cyt b as well as the slow phase of cyt f reduction were increased. The BQ-induced effects were largely reversed by addition of MOA-stilbene, indicating that the oxidation of cyt b by BQ is most likely catalyzed by the Qi-site. We conclude that the primary pathway for plastoquinol oxidation at the Qo-site is via a classical oxidant-induced reduction mechanism and does not occur via a semiquinone (SQ) cycle or any other mechanism that allows reduction of the high-potential chain without a concerted reduction of the low-potential chain.

[1]  S. Kato,et al.  Studies on electron transport associated with photosystem I. 3. The reduction sites of various Hill oxidants in the photosynthetic electron transport system. , 1973, Biochimica et biophysica acta.

[2]  P. Rich A critical examination of the supposed variable proton stoichiometry of the chloroplast cytochrome bf complex , 1988 .

[3]  P. Joliot,et al.  Electron transfer between the two photosystems. I: Flash excitation under oxidizing conditions , 1984 .

[4]  D. Ort,et al.  Quantitation of the rapid electron donors to P700, the functional plastoquinone pool, and the ratio of the photosystems in spinach chloroplasts. , 1984, The Journal of biological chemistry.

[5]  B. Kok,et al.  Plastocyanin as the possible site of photosynthetic electron transport inhibition by glutaraldehyde. , 1977, Plant physiology.

[6]  D. G. Bishop,et al.  Effect of amphotericin B on membrane-associated photosynthetic reactions in maize chloroplasts. , 1978, Archives of biochemistry and biophysics.

[7]  R. Malkin,et al.  Identification of a g = 1.90 high-potential iron-sulfur protein in chloroplasts , 1975 .

[8]  Peter R. Rich,et al.  Kinetic studies of electron transfer in a hybrid system constructed from the cytochrome bf complex and Photosystem I , 1987 .

[9]  C. Yocum,et al.  Photophosphorylation Associated with Photosystem II: I. Photosystem II Cyclic Photophosphorylation Catalyzed by p-Phenylenediamine. , 1977, Plant Physiology.

[10]  S. Malkin,et al.  Fluorescence induction studies in isolated chloroplasts. I. Number of components involved in the reaction and quantum yields. , 1966, Biochimica et biophysica acta.

[11]  G. D. Winget,et al.  Site-specific Inhibition of Photophosphorylation in Isolated Spinach Chloroplasts by Mercuric Chloride. , 1973, Plant physiology.

[12]  S. Izawa,et al.  Electron transport and photophosphorylation in chloroplasts as a function of the electron acceptor. II. Acceptor-specific inhibition by KCN. , 1973, Biochimica et biophysica acta.

[13]  A. Crofts,et al.  A new electrogenic step in the ubiquinol:cytochrome c2 oxidoreductase complex of Rhodopseudomonas sphaeroides. , 1984, Biochimica et biophysica acta.

[14]  D. Bendall,et al.  The redox potentials of the b-type cytochromes of higher plant chloroplasts. , 1980, Biochimica et biophysica acta.

[15]  G. Hauska,et al.  The pH dependence of the redox midpoint potential of the 2Fe2S cluster from cytochrome b6f complex (the ‘Rieske centre’) , 1992 .

[16]  A. Crofts,et al.  THE ROLE OF THE QUINONE POOL IN THE CYCLIC ELECTRON-TRANSFER CHAIN OF RHODOPSEUDOMONAS SPHAEROIDES: A MODIFIED Q-CYCLE MECHANISM. , 1983, Biochimica et biophysica acta.

[17]  Anthony N. Martonosi,et al.  The Enzymes of Biological Membranes , 1985, Springer US.

[18]  K. Krab,et al.  Respiration-Linked H+ Translocation in Mitochondria: Stoichiometry and Mechanism , 1980 .

[19]  J. Wan,et al.  Electron Spin Resonance Study of the Self-disproportionation of some Semiquinone Radicals in Solution , 1972 .

[20]  B. Kok,et al.  Redox titration of electron acceptor Q and the plastoquinone pool in photosystem II. , 1979, Biochimica et biophysica acta.

[21]  P. Joliot,et al.  Slow electrogenic phase and intersystem electron transfer in algae , 1985 .

[22]  P. Rich,et al.  Electron and proton transfers through quinones and cytochrome bc complexes. , 1984, Biochimica et biophysica acta.

[23]  P. Mitchell,et al.  Possible molecular mechanisms of the protonmotive function of cytochrome systems. , 1976, Journal of theoretical biology.

[24]  R. Giaquinta,et al.  Evidence for cyanide and mercury inactivation of endogenous plastocyanin , 1975 .

[25]  D. Ort,et al.  Effects of the plastocyanin antagonists KCN and poly‐l‐lysine on partial reactions in isolated chloroplasts , 1973, FEBS letters.

[26]  A. Crofts,et al.  The electrochemical domain of photosynthesis , 1983 .

[27]  G. Feher,et al.  Current Research in Photosynthesis , 1990, Springer Netherlands.

[28]  D. Devault,et al.  The site of KCN inhibition in the photosynthetic electron transport pathway. , 1973, Biochimica et biophysica acta.

[29]  D. Bendall,et al.  An EPR analysis of the partially purified cytochrome bf complex of higher‐plant chloroplasts , 1980 .