Inhibitory effects of dicyclohexylcarbodiimide on spinach cytochrome b6-f complex

The electron transfer activity of purified cytochrome b6-f complex of spinach chloroplast is inhibited by dicyclohexylcarbodiimide (DCCD) in a concentration and incubation time dependent manner. The maximum inhibition of 75% is observed when 300 mole of DCCD per mole of protein (based on cytochrome f) is incubated with cytochrome b6-f complex at room temperature for 40 min. The inhibition of the complex is not due to the formation of cross links between subunits but due to the modification of carboxyls. The amount of DCCD incorporation is directly proportional to the activity loss, suggesting that some carboxyl groups in the complex are directly or indirectly involved in the catalytic function. The incorporated DCCD is located mainly at cytochrome b6 protein. The partially inhibited complex shows the same H+/e-ratio as that of the intact complex when embedded in phospholipid vesicles.     

Association of cytochrome b5 and cytochrome P-450 reductase with cytochrome P-450 in the membrane of reconstituted vesicles

A protein-protein association of cytochrome P-450 LM2 with NADPH-cytochrome P-450 reductase, with cytochrome b5, and with both proteins was demonstrated in reconstituted phospholipid vesicles by magnetic circular dichroism difference spectra. A 23% decrease in the absolute intensity of the Soret band of the magnetic CD spectrum of cytochrome P-450 was observed when it was reconstituted with reductase. A difference spectrum corresponding to a 7% decrease in absolute intensity was obtained when cytochrome b5 was incorporated into vesicles that already contained cytochrome P-450 and cytochrome P-450 reductase compared to a decrease of 13% in absolute intensity when cytochrome b5 was incorporated into vesicles that contained only cytochrome P-450. The use of the magnetic circular dichroism confirmed that protein-protein associations that have been detected by absorption spectroscopy between purified and detergent-solubilized proteins also exist in membranes. High ionic strength was shown to interrupt direct electron flow from cytochrome P-450 reductase to cytochrome P-450 but not the electron flow from reductase through cytochrome b5 to cytochrome P-450. Upon incorporation of cytochrome b5 into cytochrome P-450- and cytochrome P-450 reductase-containing vesicles, an increase of benzphetamine N-demethylation activity was observed. The magnitude of this increase was numerically identical to the residual activity of the reconstituted vesicles measured in the presence of 0.3 M KCl. It is concluded that there is a requirement for at least one charge pairing for electron transfer from reductase to cytochrome P-450. These observations are combined in a proposed mechanism of coupled reversible association reactions in the membrane.     

Functional activities of monomeric and dimeric forms of the chloroplast cytochrome b6f complex

A monomeric form of the isolated cytochrome b6f complex from spinach chloroplast membranes has been isolated after treatment of the dimeric complex with varying concentrations of Triton X-100. The two forms of the complex are similar as regards electron transfer components and subunit composition. In contrast to a previous report (Huang et al. (1994) Biochemistry 33: 4401–4409) both the monomer and dimer are enzymatically active. However, after incorporation of the respective complexes into phospholipid vesicles, only the dimeric form of the cytochrome complex shows uncoupler sensitive electron transport, an indication of coupling of electron transport to proton translocation. The absence of this activity with the monomeric form of the cytochrome complex may be related to an inhibition by added lipids.Abbreviations CCCP- carbonyl cyanide m-chlorophenylhydrazone - mega-9- nonanoyl-N-methylglucamide     

Low-potential cytochrome b as an essential electron-transport component of menaquinone reduction by formate in Vibrio succinogenes

Incorporation of the electron-transport enzymes of Vibrio succinogenes into liposomes was used to investigate the question of whether, in this organism, a cytochrome b is involved in electron transport from formate to fumarate on the formate side of menaquinone. (1) Formate dehydrogenase lacking cytochrome b was prepared by splitting the cytochrome from the formate dehydrogenase complex. The enzyme consisted of two different subunits (Mr 110 000 and 20 000), catalyzed the reduction of 2,3-dimethyl-1,4-naphthoquinone by formate, and could be incorporated into liposomes. (2) The modified enzyme did not restore electron transport from formate to fumarate when incorporated into liposomes together with vitamin K-1 (instead of menaquinone) and fumarate reductase complex. In contrast, restoration was observed in liposomes that contained formate dehydrogenase with cytochrome b (Em = -224 mV), in addition to the subunits mentioned above (formate dehydrogenase complex). (3) In the liposomes containing formate dehydrogenase complex and fumarate reductase complex, the response of the cytochrome b of the formate dehydrogenase complex was consistent with its interaction on the formate side of menaquinone in a linear sequence of the components. The low-potential cytochrome b associated with fumarate reductase complex was not reducible by formate under any condition. It is concluded that the low-potential cytochrome b of the formate dehydrogenase complex is an essential component in the electron transport from formate to menaquinone. The low-potential cytochrome b of the fumarate reductase complex could not replace the former cytochrome in restoring electron-transport activity.     

Photosynthetic electron transfer through the cytochrome b6f complex can bypass cytochrome f

The cytochrome b(6)f complex is an obligatory electron transfer and proton-translocating enzyme in all oxygenic photosynthesis. Its operation has been described by the "Q-cycle." This model proposes that electrons are transferred from plastoquinol to plastocyanin (the reductant of P700 in Photosystem I) through, obligatorily in series, the iron-sulfur and the cytochrome f redox centers in the cytochrome b(6)f complex. However, here we demonstrate that (a) the iron-sulfur center-dependent reductions of plastocyanin and P700 are much faster than cytochrome f reduction, both in Chlamydomonas reinhardtii cytochrome f mutants and in the wild type, and (b) the steady-state photosynthetic electron transport does not correlate with strongly inhibited cytochrome f reduction kinetics in the mutants. Thus, cytochrome f is not an obligatory intermediate for electrons flowing through the cytochrome b(6)f complex. The oxidation equivalents from Photosystem I are delivered to the high potential chain of the cytochrome b(6)f complex both at the cytochrome f level and, independently, at another site connected to the quinol-oxidizing site, possibly the iron-sulfur center.     

Light inhibition of respiration is due to a dual function of the cytochrome b6-f complex and the plastocyanin/cytochrome c-553 pool in Aphanocapsa

Studies of the respiratory electron transport pathway in the blue-green alga, Aphanocapsa, demonstrated the presence of cytochrome oxidase and a cytochrome complex. The use of antimycin A showed only the occurrence of a plastidal type of cytochrome complex (the cytochrome b6-f complex), which is insensitive to this inhibitor. Determination of the extent of photooxidation of cytochromes c-553 and f-556 under conditions of high and low cytochrome oxidase activities indicated an electron flow through both cytochromes to cytochrome oxidase. Direct evidence for a common segment of photosynthetic and respiratory electron transport from plastoquinone via the cytochrome b6-f complex to the soluble plastocyanin/cytochrome c-553 pool, as well as a competition between cytochrome oxidase and Photosystem I for reductants in this pool in the light, was obtained by measurements of electron transport with suitable electron donors in this alga.     

Ferredoxin:NADP+ oxidoreductase is a subunit of the chloroplast cytochrome b6f complex

Purified detergent-soluble cytochrome b6f complex from chloroplast thylakoid membranes (spinach) and cyanobacteria (Mastigocladus laminosus) was highly active, transferring 300-350 electrons per cyt f/s. Visible absorbance spectra showed a red shift of the cytochrome f alpha-band and the Qy chlorophyll a band in the cyanobacterial complex and an absorbance band in the flavin 450-480-nm region of the chloroplast complex. An additional high molecular weight (M(r) approximately 35,000) polypeptide in the chloroplast complex was seen in SDS-polyacrylamide gel electrophoresis at a stoichiometry of approximately 0.9 (cytochrome f)(-1). The extra polypeptide did not stain for heme and was much more accessible to protease than cytochrome f. Electrospray ionization mass spectrometry of CNBr fragments of the 35-kDa polypeptide was diagnostic for ferredoxin:NADP+ oxidoreductase (FNR), as were antibody reactivity to FNR and diaphorase activity. The absence of FNR in the cyanobacterial complex did not impair decyl-plastoquinol-ferricyanide activity. The activity of the FNR in the chloroplast b6f complex was also shown by NADPH reduction, in the presence of added ferredoxin, of 0.8 heme equivalents of the cytochrome b6 subunit. It was inferred that the b6f complex with bound FNR, one equivalent per monomer, provides the membrane protein connection to the main electron transfer chain for ferredoxin-dependent cyclic electron transport.     

The catalytic role of subunit IV of the cytochrome b6-f complex from spinach chloroplast

The catalytic role of subunit IV, the Mr 17,000 protein, in the chloroplast cytochrome b6-f complex was established through trypsinolysis of the complex under controlled conditions. When purified chloroplast cytochrome b6-f complex, 1 mg/ml, in 50 mM Tris-succinate buffer (pH 7.0) containing 1% sodium cholate and 10% glycerol is treated with 80 micrograms of trypsin at room temperature for various lengths of time, the activity of the cytochrome b6-f complex decreases as the incubation time increases. A maximal inactivation of 80% is reached at 7 min of incubation. The trypsin inactivation is accompanied by the destruction of the proton translocation activity of the complex. No alteration of absorption and EPR spectral properties was observed in the trypsin-inactivated complex. Subunit IV is the only subunit in the cytochrome b6-f complex that is digested by trypsin, and the degree of digestion correlates with the decrease of electron transfer activity. The binding of azido-Q to subunit IV of the complex decreases as the extent of inactivation of the cytochrome b6-f complex by trypsin increases. The residue molecular mass of trypsin cleaved subunit IV is about 14 kDa, suggesting that the cleavage site is at lysine 119 or arginine 125 or 126. When the thylakoid membrane was assayed for cytochrome b6-f complex activity, very little activity was observed; and the activity was not sensitive to trypsinolysis. Upon sonication, activity and sensitivity to trypsinolysis was greatly increased, suggesting that subunit IV protrudes from the lumen side of the membrane.     

Quinone interactions with the chloroplast cytochrome b6-f complex

The requirements for reconstitution of electron transfer activity with a plastoquinone (PQ)-depleted cytochrome b6-f complex from spinach have been considered. Full restoration of activity measured as plastocyanin reduction with either duroquinol in the dark or Photosystem II (PSII) in the light requires both PQ-9 and phospholipid. However, a substantial dark activity can be observed with duroquinol and phospholipid in the absence of any added PQ-9. PSII, with its associated PQ molecules, can also donate electrons in the light to the cytochrome complex which has been depleted of plastoquinone. Electron donation by duroquinol in the dark to the PQ-depleted cytochrome complex is stimulated by PSII, and this stimulation is dependent on the presence of the two PQ molecules in the PSII preparation. Measurements of proton translocation with the PQ-depleted complex indicate this quinone is not required for the observed H+/e- ratio of 2. Studies of cytochrome b6 kinetics with the free and liposome-incorporated PQ-depleted complex show this cytochrome undergoes redox reactions similar to those of a control complex which contains PQ. These results indicate the PQ that copurifies with the cytochrome complex is not essential for any of the measured activities. These findings are considered in relation to a quinone binding site(s) in the cytochrome complex which is not specific to PQ but can bind other quinones, such as duroquinol, in a lipid-dependent process.     

Coupled plasmon-waveguide resonance spectroscopy studies of the cytochrome b6f/plastocyanin system in supported lipid bilayer membranes.

The incorporation of cytochrome (cyt) b6f into a solid-supported planar egg phosphatidylcholine (PC) bilayer membrane and complex formation with plastocyanin have been studied by a variant of surface plasmon resonance called coupled plasmon-waveguide resonance (CPWR) spectroscopy, developed in our laboratory. CPWR combines greatly enhanced sensitivity and spectral resolution with direct measurement of anisotropies in refractive index and optical extinction coefficient, and can therefore probe structural properties of lipid-protein and protein-protein interactions. Cyt b6f incorporation into the membrane proceeds in two stages. The first occurs at low protein concentration and is characterized by an increase in total proteolipid mass without significant changes in the molecular order of the system, as demonstrated by shifts of the resonance position to larger incident angles without changing the refractive index anisotropy. The second stage, occurring at higher protein concentrations, results in a decrease in both the mass density and the molecular order of the system, evidenced by shifts of the resonance position to smaller incident angles and a large decrease in the membrane refractive index anisotropy. Plastocyanin can bind to such a proteolipid system in three different ways. First, the addition of plastocyanin before the second stage of b6f incorporation begins results in complex formation between the two proteins with a KD of approximately 10 microM and induces structural changes in the membrane that are similar to those occurring during the second stage of complex incorporation. The addition of larger amounts of plastocyanin under these conditions leads to nonspecific binding to the lipid phase with a KD of approximately 180 microM. Finally, the addition of plastocyanin after the completion of the second phase of b6f incorporation results in tighter binding between the two proteins (KD approximately 1 microM). Quantitation of the binding stoichiometry indicates that two plastocyanin molecules bind tightly to the dimeric form of the cyt b6f complex, assuming random insertion of the cytochrome into the bilayer. The structural basis for these results and formation of the proteolipid membrane are discussed.     

A regulatory role of the PetM subunit in a cyanobacterial cytochrome b6f complex

To investigate the function of the PetM subunit of the cytochrome b6f complex, the petM gene encoding this subunit was inactivated by insertional mutagenesis in the cyanobacterium Synechocystis PCC 6803. Complete segregation of the mutant reveals a nonessential function of PetM for the structure and function of the cytochrome b6f complex in this organism. Photosystem I, photosystem II, and the cytochrome b6f complex still function normally in the petM- mutant as judged by cytochrome f re-reduction and oxygen evolution rates. In contrast to the wild type, however, the content of phycobilisomes and photosystem I as determined from 77 K fluorescence spectra is reduced in the petM- strain. Furthermore, whereas under anaerobic conditions the kinetics of cytochrome f re-reduction are identical, under aerobic conditions these kinetics are slower in the petM- strain. Fluorescence induction measurements indicate that this is due to an increased plastoquinol oxidase activity in the mutant, causing the plastoquinone pool to be in a more oxidized state under aerobic dark conditions. The finding that the activity of the cytochrome b6f complex itself is unchanged, whereas the stoichiometry of other protein complexes has altered, suggests an involvement of the PetM subunit in regulatory processes mediated by the cytochrome b6f complex.     

Functional implications of pigments bound to a cyanobacterial cytochrome b6f complex

A highly purified cytochrome b(6)f complex from the cyanobacterium Synechocystis sp. PCC 6803 selectively binds one chlorophyll a and one carotenoid in analogy to the recent published structure from two other b(6)f complexes. The unknown function of these pigments was elucidated by spectroscopy and site-directed mutagenesis. Low-temperature redox difference spectroscopy showed red shifts in the chlorophyll and carotenoid spectra upon reduction of cytochrome b(6), which indicates coupling of these pigments with the heme groups and thereby with the electron transport. This is supported by the correlated kinetics of these redox reactions and also by the distinct orientation of the chlorophyll molecule with respect to the heme cofactors as shown by linear dichroism spectroscopy. The specific role of the carotenoid echinenone for the cytochrome b(6)f complex of Synechocystis 6803 was elucidated by a mutant lacking the last step of echinenone biosynthesis. The isolated mutant complex preferentially contained a carotenoid with 0, 1 or 2 hydroxyl groups (most likely 9-cis isomers of beta-carotene, a monohydroxy carotenoid and zeaxanthin, respectively) instead. This indicates a substantial role of the carotenoid - possibly for strucure and assembly - and a specificity of its binding site which is different from those in most other oxygenic photosynthetic organisms. In summary, both pigments are probably involved in the structure, but may also contribute to the dynamics of the cytochrome b(6)f complex.     

DCCD binds to cytochrome b6 of a cytochrome bf complex isolated from spinach chloroplasts and inhibits proton translocation.

Radiolabeled N,N'-dicyclohexylcarbodiimide (DCCD) was bound selectively in a time- and concentration-dependent manner to cytochrome b6 of an enzymatically active cytochrome bf complex isolated from spinach chloroplasts. Maximum labeling of cytochrome b6 was observed with 30 nmol DCCD per nmol cytochrome b6 in the cytochrome bf complex incubated for 30-60 min at 12 degrees C. After incubation of the cytochrome bf complex with DCCD under these conditions, the rate of proton ejection in the complex reconstituted into liposomes was decreased approximately 65-70% when compared to controls; however, under these same conditions the rate of electron transfer through either the soluble bf complex or the complex reconstituted into liposomes was only decreased around 20%. These results suggest that the mechanism of proton translocation through the cytochrome bf complex of spinach chloroplasts is similar to that of the cytochrome bc1 complex from yeast mitochondria in which proton pumping but not electron transfer is also inhibited by DCCD (D. S. Beattie and A. Villalobo, 1982, J. Biol. Chem. 257, 14,745-14,752).     

A ubiquinone derivative that inhibits mitochondrial cytochrome b-c1 complex but not chloroplast cytochrome b6-f complex activity

A ubiquinone derivative, 3-chloro-5-hydroxyl-2-methyl-6-decyl- 1,4-benzoquinone (3-CHMDB), which shows different effects on the mitochondrial cytochrome b-c1 complex and chloroplast cytochrome b6-f complex, has been synthesized and characterized. When the cytochrome b-c1 complex is treated with varying concentrations of 3-CHMDB and assayed at constant substrate (Q2H2) concentration, a 50% inhibition is observed when 2 mol of 3-CHMDB per mol of enzyme are used. The degree of inhibition is dependent on the substrate concentration. When ubiquinol-cytochrome c reductase is treated with 2 mol of 3-CHMDB per mol of enzyme, less inhibition is observed with a lower substrate concentration, suggesting the possible existence of two forms of reductases: one with a high affinity for ubiquinone and another with a low affinity. 2-Chloro-5-hydroxyl-3-methyl-6-decyl-1,4-benzoquinone (2-CHMDB), an isomer of 3-CHMDB, shows much less inhibition of the mitochondrial cytochrome b-c1 complex, suggesting that the quinone binding site in this complex is highly specific. In contrast to the inhibition observed with the cytochrome b-c1 complex, 3-CHMDB causes no inhibition of the plastoquinol-plastocyanin reductase activity of chloroplast cytochrome b6-f complex, regardless of whether plastoquinol-2 or ubiquinol-2 is used as substrate. 3-CHMDB restores the dibromothymoquinone-altered EPR spectra of iron-sulfur protein in both complexes. In the case of the cytochrome b6-f complex, 3-CHMDB also partially restores the dibromothymoquinone-inhibited activity. Reduced form 3- or 2-CHMDB is oxidizable by the cytochrome b6-f complex, but not by the cytochrome b-c1 complex. These results suggest that the quinol oxidizing sites in the cytochrome b6-f complex may differ from those in the mitochondrial cytochrome b-c1 complex.     

Electron transfer and stability of the cytochrome b6f complex in a small domain deletion mutant of cytochrome f

The lumen segment of cytochrome f consists of a small and a large domain. The role of the small domain in the biogenesis and stability of the cytochrome b(6)f complex and electron transfer through the cytochrome b(6)f complex was studied with a small domain deletion mutant in Chlamydomonas reinhardtii. The mutant is able to grow photoautotrophically but with a slower rate than the wild type strain. The heme group is covalently attached to the polypeptide, and the visible absorption spectrum of the mutant protein is identical to that of the native protein. The kinetics of electron transfer in the mutant were measured by flash kinetic spectroscopy. Our results show that the rate for the oxidation of cytochrome f was unchanged (t(12) = approximately 100 micros), but the half-time for the reduction of cytochrome f is increased (t(12) = 32 ms; for wild type, t(12) = 2.1 ms). Cytochrome b(6) reduction was slower than that of the wild type by a factor of approximately 2 (t(12) = 8.6 ms; for wild type, t(12) = 4.7 ms); the slow phase of the electrochromic band shift also displayed a slower kinetics (t(12) = 5.5 ms; for wild type, t(12) = 2.7 ms). The stability of the cytochrome b(6)f complex in the mutant was examined by following the kinetics of the degradation of the individual subunits after inhibiting protein synthesis in the chloroplast. The results indicate that the cytochrome b(6)f complex in the small domain deletion mutant is less stable than in the wild type. We conclude that the small domain is not essential for the biogenesis of cytochrome f and the cytochrome b(6)f complex. However, it does have a role in electron transfer through the cytochrome b(6)f complex and contributes to the stability of the complex.     

Redox-coupled proton pumping activity in cytochrome b6f,as evidenced by the pH dependence of electron transfer in whole cells of Chlamydomonas reinhardtii

The pH dependence of cytochrome b(6)f catalytic activity has been measured in whole cells of the green alga Chlamydomonas reinhardtii over the 5-8 range. An acid pH slowed the reactions occurring at the lumenal side of the complex (cytochrome b(6) and f reduction) and affected also the rate and amplitude of the slow electrogenic reaction (phase b), which is supposed to reflect transmembrane electron flow in the complex. On the other hand, a direct measurement of the transmembrane electron flow from the kinetics of cytochrome b(6) oxidation revealed no pH sensitivity. This suggests that a substantial fraction of the electrogenicity associated with cytochrome b(6)f catalysis is not due to electron transfer in the b(6) hemes but to a plastoquinol-oxidation-triggered charge movement, in agreement with previous suggestions that a redox-coupled proton pump operates in cytochrome b(6)f complex. The pH dependence of cytochrome b(6)f activity has also been measured in two mutant strains, where the glutamic 78 of the conserved PEWY sequence of subunit IV has been substituted for a basic (E78K) and a polar (E78Q) residue [Zito, F., Finazzi, G., Joliot, P., and Wollman, F.-A. (1998) Biochemistry 37, 10395-10403]. Their comparison with the wild type revealed that this residue plays an essential role in plastoquinol oxidation at low pH, while it is not required for efficient activity at neutral pH. Its involvement in gating the redox-coupled proton pumping activity is also shown.     

The pgr1 mutation in the Rieske subunit of the cytochrome b6f complex does not affect PGR5-dependent cyclic electron transport around photosystem I

Although photosystem I (PSI) cyclic electron transport is essential for plants, our knowledge of the route taken by electrons is very limited. To assess whether ferredoxin (Fd) donates electrons directly to plastoquinone (PQ) or via a Q-cycle in the cytochrome (cyt) b(6)f complex in PSI cyclic electron transport, we characterized the activity of PSI cyclic electron transport in an Arabidopsis mutant, pgr1 (proton gradient regulation). In pgr1, Q-cycle activity was hypersensitive to acidification of the thylakoid lumen because of an amino acid alteration in the Rieske subunit of the cyt b(6)f complex, resulting in a conditional defect in Q-cycle activity. In vitro assays using ruptured chloroplasts did not show any difference in the activity of PGR5-dependent PQ reduction by Fd, which functions in PSI cyclic electron transport in vivo. In contrast to the pgr5 defect, the pgr1 defect did not show any synergistic effect on the quantum yield of photosystem II in crr2-2, a mutant in which NDH (NAD(P)H dehydrogenase) activity was impaired. Furthermore, the simultaneous determination of the quantum yields of both photosystems indicated that the ratio of linear and PSI cyclic electron transport was not significantly affected in pgr1. All the results indicated that the pgr1 mutation did not affect PGR5-dependent PQ reduction by Fd. The phenotypic differences between pgr1 and pgr5 indicate that maintenance of the proper balance of linear and PSI cyclic electron transport is essential for preventing over-reduction of the stroma.