The relationship between the activity of chloroplast Photosystem II and the midpoint oxidation-reduction potential of cytochrome b-559

The role of cytochrome b-559 in Photosystem II reactions has been investigated using hydroxylamine treatment of chloroplast membranes. Incubation of chloroplasts with hydroxylamine in darkness resulted in inhibition of water oxidation and a decrease in the amplitude of cytochrome b-559 reducible by hydroquinone. The loss of water oxidizing activity perfectly correlated with the decrease in amplitude of cytochrome b-559 reduction. Potentiometric titration of cytochrome b-559 after hydroxylamine treatment revealed a component with E_m7.8 at +240 mV in addition to a lower potential species at +90 mV. This compared to control chloroplasts in which cytochrome b-559 exists in the typical high potential state, E_m7.8 = +383 mV, in addition to some of the low potential (E_m7.8 = +77 mV) form. Photosystem II activity could be further inhibited by incubation with hydroxylamine in the light. In these chloroplasts only low rates of photooxidation of artificial electron donors were observed compared to ‘dark’ chloroplasts. In addition, the hydroxylamine light treatment caused a further change in cytochrome b-559 redox properties; a single component, E_m7.8 = 90 mV is seen in titration curves. The role of cytochrome b-559 in Photosystem II functioning is discussed on the basis of these observations which suggest a dependence of photooxidizing ability of Photosystem II on the redox properties of this cytochrome.     

Light-induced oxidation-reduction reactions in a cell-free preparation from the blue-green alga Nostoc muscorum: The role of cytochrome f, cytochrome b558, C550, and P700 in noncyclic electron transport

1. Cytochrome f (λ_max = 554 nm, E_m = +0.35 V) and cytochrome b₅₅₈ (λ_max = 558 nm, E_m = +0.35 V) were photooxidized by Photosystem I and photoreduced by Photosystem II in a cell-free preparation from the blue-green alga Nostoc muscorum. The steady-state oxidation levels of both cytochromes were affected by noncyclic electron acceptors and by inhibitors of noncyclic electron transport. These results are consistent with the hypothesis that the mechanism of NADP reduction by water involves a Photosystem II and a Photosystem I light reaction operating in series and linked by a chain of electron carriers that includes cytochrome f and cytochrome b₅₅₈.2. Phosphorylation cofactors shifted the steady-state of cytochrome f to a more reduced level under conditions of noncyclic electron transport but had no effect on cytochrome b₅₅₈. These observations suggest that the noncyclic phosphorylation site lies before cytochrome f (on the Photosystem II side) and that cytochrome f is closer to this site than is cytochrome b₅₅₈.3. A Photosystem II photoreduction of C550 at 77 °K was observed, suggesting that in blue-green algae, as in other plants, C550 is closely associated with the primary electron acceptor for Photosystem II. A Photosystem I photooxidation of P700 at 77 °K was observed, consistent with P700 serving as the primary electron donor of Photosystem I.     

Oxidation-reduction properties of the electron acceptors of Photosystem II. II. Redox titration at various pH values of the flash-induced formation of C550 in Chlamydomonas Photosystem II particles lacking the secondary quinone electron acceptor

Redox titrations of the flash-induced formation of C550 (a linear indicator of Q^?) were performed between pH 5.9 and 8.3 in Chlamydomonas Photosystem II particles lacking the secondary electron acceptor, B. One-third of the reaction centers show a pH-dependent midpoint potential (E_m,7.5) = ? 30 mV) for redox couple $\text{Q}\text{Q}{}^{\mathrm{?}}$, which varies by ?60 mV/pH unit. Two-thirds of the centers show a pH-independent midpoint potential (E_mm = + 10 mV) for this couple. The elevated pH-independent E_m suggests that in the latter centers the environment of Q has been modified such as to stabilize the semiquinone anion, Q^?. The midpoint potentials of the centers having a pH-dependent E_m are within 20 mV of those observed in chloroplasts having a secondary electron acceptor. It appears therefore that the secondary electron acceptor exerts little influence on the E_m of $\text{Q}\text{Q}{}^{\mathrm{?}}$. An EPR signal at g 1.82 has recently been attributed to a semiquinone-iron complex which comprises Q^?. The similar redox behavior reported here for C550 and reported by others (Evans, M.C.W., Nugent, J.H.A., Tilling, L.A. and Atkinson, Y.E. (1982) FEBS Lett. 145, 176–178) for the g 1.82 signal in similar Photosystem II particles confirm the assignment of this EPR signal to Q^?. At below ?200 mV, illumination of the Photosystem II particles produces an accumulation of reduced pheophytin (Ph^?). At ?420 mV Ph^? appears with a quantum yield of 0.006–0.01 which in this material implies a lifetime of 30–100 ns for the radical pair P-680⁺Ph^?.     

Effect of oxidation-reduction potential on light-induced cytochrome and bacteriochlorophyll reactions in chromatophores from the photosynthetic green bacterium Chlorobium

The reaction center bacteriochlorophyll of Chlorobium thiosulfatophilum has a midpoint oxidation-reduction potential (E_m) of +330 mV. Its photooxidation is unaffected by oxidation-reduction potentials in the range from +260 mV to ?70 mV but on further reduction is attenuated to zero in a one-electron transition with an E_m of ?130 mV.A c-type cytochrome with an E_m of +220 mV and absorption maxima at 551–552 nm (α-band) and 420 nm (γ-band) is present in Chlorobium chromatophores and undergoes photooxidation. Cytocrome c photooxidation is attenuated to zero in two 1-electron steps with E_m of +30 mV and ?130 mVPossible roles for +30 mV and ?130 mV components in photosynthetic electron transport in Chlorobium are discussed.     

The oxidation-reduction potentials of the hemes and copper of cytochrome oxidase from beef heart

The oxidation-reduction potentials of the heme and copper components of isolated beef heart cytochrome oxidase have been studied by potentiometric techniques. In highly purified preparations the two heme components give a single titration curve with a midpoint potential at pH 7.0 (E_m^7.0) of +285 mV and an n value of 0.5. In partially purified preparations the heme components could be resolved into a high potential cytochrome (a₃) (E_m^7.0 = +375 mV, an n value of 1.0) and a low potential cytochrome (a) (E_m^7.0 = +225 mV, an n value of 1.0). In general, with decrease in enzymatic activity the E_m^7.0 of the high potential component becomes more negative.     

A method for in situ characterization of b- and c-type cytochromes in Escherichia coli and in Complex III from beef heart mitochondria by combined spectrum deconvolution and potentiometric analysis

An analytical technique for the in situ characterization of b- and c-type cytochromes has been developed. From evaluation of the results of potentiometric measurements and spectrum deconvolutions, it was concluded that an integrated best-fit analysis of potentiometric and spectral data gave the most reliable results. In the total cytochrome b content of cytoplasmic membranes from aerobically grown Escherichia coli, four major components are distinguished with α-band maxima at 77 K of 555.7, 556.7, 558.6 and 563.5 nm, and midpoint potentials at pH 7.0 of 46, 174, ?75 and 187 mV, respectively. In addition, two very small contributions to the α-band spectrum at 547.0 and 560.2 nm, with midpoint potentials of 71 and 169 mV, respectively, have been distinguished. On the basis of their spectral properties they should be designated as a cytochrome c and a cytochrome b, respectively. In Complex III, isolated from beef heart mitochondria, five cytochromes are distinguished: cytochrome c₁ (Λ_m(25°C) = 553.5 nm; E′₀ = 238 mV) and four cytochromes bΛ_m(25°C) = 558.6, 561.2, 562.1, 566.1 nm and E′₀ = ?83, 26, 85, ?60 mV).     

Oxidation-reduction potentials of cytochromes P-450 and ferredoxin in the bovine adrenal: Their modification by substrates and inhibitors

The midpoint reduction potentials of the haem iron in bovine adrenal cytochrome P-450 and its associated iron-sulphur protein, adrenal ferredoxin, have been measured, using EPR spectroscopy to monitor the high and low spin ferric haem iron and reduced adrenal ferredoxin signals as a function of potential, in mitochondrial and microsomal suspensions.In mitochondria the high spin (substrate-bound) cytochrome P-450 showed single-component one-electron plots under most conditions; at pH 6.65 cholesterol side-chain cleavage cytochrome P-450 (P-450_scc) had a midpoint E_m = ?305 mV; at pH 8.0 11β-hydroxylase cytochrome P-450 (P-450_11β) had E_m = ?335 mV. Low spin cytochrome P-450 showed more complex titration curves under all conditions, which could be most simply interpreted in terms of two one-electron components with midpoint potentials approx. ?360 and ?470 mV, with varying intensities. During treatments that caused substrate binding, only the ?470 mV component was reduced in magnitude. On sonication and removal of adrenal ferredoxin, the ?470 mV low spin component was converted to higher potential. The potentials could also be altered by the cytochrome P-450 inhibitors aminoglutethimide and metyrapone. In the microsomes, a high spin component of cytochrome P-450 (E_m ≈ ?290 mV) was observed even at pH 8.0, suggesting the binding of an endogenous substrate, while the low spin P-450 showed a predominance of the ?360 mV component. The midpoint potential of membrane-bound adrenal ferredoxin under these various conditions was found to be ?248 mV ± 15 mV.     

Thermodynamic and EPR characterization of mitochondrial succinate-cytochrome c reductase-phospholipid complexes

Succinate-cytochrome c reductase can be easily solubilized in a phospholipid mixture (1:1, lysolecithin:lecithin) in the absence of detergents. The resulting solution contains two b cytochromes with half-reduction potentials of 95 ± 10 mV (b₅₆₁), and 0 ± 10 mV (b₅₆₆) and cytochrome c₁ (E_{m 7.2} = +280±5 mV). The oxidation-reduction midpoint potentials obtained by optical potentiometric titrations are identical to those determined by the EPR titrations and are 40–60 mV higher than the corresponding midpoint potentials of these cytochromes in intact mitochondria. In contrast to detergent-suspended preparations, no CO-sensitive cytochrome b can be detected in the phospholipid-solubilized preparation or intact mitochondria. The half-reduction potential of cytochrome b₅₆₆ is pH-dependent above pH 7.0 (?60 mV/pH unit) while that of b₅₆₁ is essentially pH-independent from pH 6.7–8.5, in contrast to its pH dependence in intact mitochondria. EPR characterizations show the presence of three oxidized low-spin heme-iron signals with g values of 3.78, 3.41 and 3.37. The identification of these signals with cytochromes b₅₆₆ (b_T), b₅₆₁ (b_K) and c₁ respectively is made on the basis of redox midpoint potentials. No significant amounts of oxidized high-spin heme-iron are detectable. In addition, the preparation contains four distinct types of iron-sulfur centers: S₁ and S₂ (E_{m 7.4} = ?260 mV and 0 mV), and two iron-sulfur proteins which are associated with the cytochrome b-c₁ complex: Rieske's iron-sulfur protein (E_{m 7.4} = +280 mV) and Ohnishi's Center 5 (E_{m 7.4} = +35 mV).     

Effect of phospholipid on the redox potential and enzymic properties of cytochromes b.

The effects of phospholipid on the redox behavior of b cytochromes in succinate-cytochrome c reductase, the cytochrome b-c₁ complex, and an isolated cytochrome b preparation were investigated by the oxidative and reductive titrations. Three E_m values of cytochrome b were observed in the phospholipid-sufftcient and -depleted succinate-cytochrome c reductase. Their midpoint potentials at pH 7.4 are 75, 75, and ?100 mV for the sufficient and 10, ?30, and ?160 mV for the depleted reductase. The molar distribution of the b cytochromes of these E_m values correspond to 30, 30, and 40%, respectively. The E_m values of the isolated cytochrome b preparations were not affected by addition of phospholipids. The isolated b preparation contained two components of equal concentration with E_m values of ?85 and ?200 mV. No direct correlation between enzymic activity and the amount of high potential b cytochromes present in the systems was demonstrated. Very little difference was observed in redox behavior of b cytochromes between the aged inactive preparations of phospholipid-depleted reductase and that of freshly prepared reconstitutively active enzyme.     

The redox potentials of the b-type cytochromes of higher plant chloroplasts

1. In fresh chloroplasts, three b-type cytochromes exist. These are b-559_HP (λ_max, 559 nm; E_m at pH 7, +370 mV; pH-independent E_m), b-559_LP (λ_max, 559 nm; E_m at pH 7, +20 mV; pH-independent E_m) and b-563 (λ_max, 563 nm; E_m at pH 7, ?110 mV; pH-independent E_m). b-559_HP may be converted to a lower potential form (λ_max, 559 nm; E_m at pH 7, +110 mV; pH-independent E_m).2. In catalytically active b-f particle preparations, three cytochromes exist. These are cytochrome f (λ_max, 554 nm; E_m at pH 7, +375 mV, pK on oxidised cytochrome at pH 9), b-563 (λ_max, 563 nm; E_m at pH 7, ?90 mV, small pH-dependence of E_m) and a b-559 species (λ_max, 559 nm, E_m at pH 7, +85 mV; pH-independent E_m).3. A positive method of demonstration and estimation of b-559_LP in fresh chloroplasts is described which involves the use of menadiol as a selective reductant of b-559_LP.     

Identification of a g equals 1.90 high-potential iron-sulfur protein in chloroplasts.

A new bound iron-sulfur protein has been identified in spinach chloroplasts. In the reduced form, this protein has an electron paramagnetic resonance spectrum at 20°K with g-values of 2.02 and 1.90. The midpoint oxidation-reduction potential (E_m) of the protein, which is pH-independent, is +290 mV. These properties are similar to those of the “Rieske” g = 1.90 iron-sulfur protein of mitochondrial Complex III.     

Role of the Rieske Iron–Sulfur Protein Midpoint Potential in the Protonmotive Q-Cycle Mechanism of the Cytochrome bc 1 Complex

The midpoint potential of the [2Fe–2S] cluster of the Rieske iron–sulfurprotein (E _{m 7} = +280mV) is the primary determinant of the rate of electron transfer from ubiquinol to cytochromec catalyzed by the cytochrome bc ₁ complex. As the midpoint potential of the Rieske clusteris lowered by altering the electronic environment surrounding the cluster, theubiquinol-cytochrome c reductase activity of the bc ₁ complex decreases; between 220 and 280 mV therate changes 2.5-fold. The midpoint potential of the Rieske cluster also affects thepresteady-state kinetics of cytochrome b and c ₁ reduction. When the midpoint potential of the Rieskecluster is more positive than that of the heme of cytochrome c ₁, reduction of cytochrome bis biphasic. The fast phase of b reduction is linked to the optically invisible reduction of theRieske center, while the rate of the second, slow phase matches that of c ₁ reduction. The ratesof b and c ₁ reduction become slower as the potential of the Rieske cluster decreases andchange from biphasic to monophasic as the Rieske potential approaches that of theubiquinone/ubiquinol couple. Reduction of b and c ₁ remain kinetically linked as the midpoint potentialof the Rieske cluster is varied by 180 mV and under conditions where the presteady statereduction is biphasic or monophasic. The persistent linkage of the rates of b and c ₁ reduction isaccounted for by the bifurcated oxidation of ubiquinol that is unique to the Q-cycle mechanism.     

Redox titration of electron acceptor Q and the plastoquinone pool in Photosystem II

The primary photochemical quencher Q and the secondary electron acceptor pool in Photosystem II have been titrated. We used particles of Scenedesmus mutant No. 8 that lack System I and allowed the system to equilibrate with external redox mediators in darkness prior to measurement of the fluorescence rise curve.The titration of Q, as indicated by the dark level of F_i, occurs in two discrete steps. The high-potential component (Q_h) has a midpoint potential of +68 mV (pH 7.2) and accounts for ～67% of Q. The pH sensitivity of the midpoint potential is ?60 mV, indicating the involvement of 1 $\text{H}{}^{\mathrm{+}}\text{e}$. The low-potential component (Q₁) accounts for the remaining 33% of Q and shows a midpoint potential near?300 mV (pH 7.2).The plastoquinone pool, assayed as the half-time of the fluorescence rise curve, titrates as a single component with a midpoint potential 30–40 mV more oxidizing than that of Q_h, i.e., at 106 mV (pH 7.2). The E_m shows a pH sensitivity of ?60 mV/pH unit, indicating the involvement of 1 $\text{H}{}^{\mathrm{+}}\text{e}$. The observation that all 12–14 electron equivalents in the pool titrate as a single component indicates that the heterogeneity otherwise observed in the secondary acceptor system is a kinetic rather than a thermodynamic property.Illumination causes peculiar, and as yet unclarified, changes of both Q and the secondary pool under anaerobic conditions that are reversed by oxygen.     

Partial purification and characterization of two soluble c-type cytochromes from Chromatium vinosum

Two c-type cytochromes from Chromatium vinosum have been partially purified and characterized. Cytochrome c₅₅₀, which appears to function as an electron carrier in the cyclic electron transport chain of this photosynthetic purple sulfur bacterium, has a molecular weight of approximately 15,000 and an oxidation-reduction midpoint potential (E_m) of + 240 mV at pH 7.4. It has (in the reduced form) an α band at 550 nm and a β band at 520 nm. Cytochrome c₅₅₁ is characterized by absorbance maxima at 354 and 409 nm in the oxidized form and 418, 523, and 551 nm in the reduced form. The reduced cytochrome reacts with CO. Cytochrome c₅₅₁ is a monomeric protein with a molecular weight of 18,800 ± 700 and E_m = ?299 ± 5 mV (pH independent between pH 6.3 and 8.0). It appears to lack a methionine axial ligand as indicated by the absence of an absorbance band at 695 nm in the oxidized form.     

Flash photolysis-electron spin resonance studies of Photosystem I. A fast reduction component of P-700+

A 300 μs decay component of ESR Signal I (P-700⁺) in chloroplasts is observed following a 10 μs actinic xenon flash. This transient is inhibited by treatments which block electron transfer from Photosystem II to Photosystem I (e.g. 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU), 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB), KCN and HgCl₂). The fast transient reduction of P-700⁺ can be restored in the case of DCMU or DBMIB inhibition by addition of an electron donor couple (2,6-dichlorophenol indophenol (Cl₂Ind)/ascorbate) which supplies electrons to cytochrome f. However, this donor couple is inefficient in restoring electron transport in chloroplasts which have been inhibited with the plastocyanin inactivators, KCN and HgCl₂. Oxidation-reduction measurements reveal that the fast P-700⁺ reduction component reflects electron transfer from a component with E_m = 375±10 mV (pH = 7.5). These data suggest the assignment of the 300-μs decay kinetics to electron transfer from cytochrome f (Fe²⁺) to P-700⁺, thus confirming the recent observations of Haehnel et al. (Z. Naturforsch. 26b, 1171–1174 (1971)).     

The effect of o-phenanthroline on the midpoint potential of the primary electron acceptor of Photosystem II

The primary electron acceptor of Photosystem II has a midpoint oxidation-reduction potential of +95 mV at pH 7.0 in Photosystem II chloroplast fragments prepared by digitonin treatment. The midpoint potential of the acceptor has a pH dependence of −60 mV/pH unit. At concentrations that inhibit oxygen evolution, o-phenanthroline shifts the midpoint potential of the primary acceptor by +70 mV. The shifted potential retains the same dependence on pH. The effect of o-phenanthroline suggests that it interacts directly with the primary electron acceptor of Photosystem II in a manner similar to that reported previously for the primary electron acceptor in purple photosynthetic bacteria.     

Oxidation-reduction properties of the electron acceptors of Photosystem II I. Redox titration of the flash-induced carotenoid band shift,of C550 and of the variable fluorescence yield in spinach chloroplasts

Redox titration of the electrochromic carotenoid band shift, detected at 50 μs after a saturating actinic flash, in spinach chloroplasts, shows that only one electron acceptor in Photosystem II participates in a transmembrane primary electron transfer. This species, the primary quinone acceptor, Q, shows only one midpoint potential (E_m,7.5) of approx. 0 V and is undoubtedly equivalent to the fluorescence quencher, Q_H. A second titration wave is observed at low potential ($\text{E}{}_{\mathrm{<mtext>m</mtext><mtext>,7.5</mtext>}}\text{? ? 240}\text{mV}$) and at greater than 3 ms after a saturating actinic flash. This wave has an action spectrum different from that of Photosystem II centers containing Q and could arise from a secondary but not primary electron transfer. A low-potential fluorescence quencher is observed in chloroplasts which largely disappears in a single saturating flash at ? 185 mV and which does not participate in a transmembrane electron transfer. This low-potential quencher (probably equivalent to fluorescence quencher, Q_L) and Q are altogether different species. Redox titration of C550 shows that if electron acceptor Q_β is indeed characterized by an E_m,7 of + 120 mV, then this acceptor does not give rise to a C550 signal upon reduction and does not participate in a transmembrane electron transfer. This titration also shows that C550 is not associated with Q_L.     

The properties of the mitochondrial succinate-cytochrome c reductase

The cytochromes b and b_T of pigeon heart mitochondria have half-reduction potentials (Em's) of +30 mV and −30 mV at pH 7.2. The midpoint potentials of these cytochromes become more negative by 30–60 mV per pH unit when the pH is made more alkaline. Detergents may be used to prepare a succinate-cytochrome c reductase free of cytochrome oxidase in which the activation of electron transport induced by oxidation of cytochrome c₁ causes the half-reduction potential of cytochrome b_T to become at least 175 mV more positive than in the absence of electron transport. This change is interpreted as indicating that the primary energy conservation reaction at site 2 remains fully functional in the purified reductase. Preliminary electron paramagnetic resonance spectra of the succinate-cytochrome c reductase as measured at near liquid helium temperatures are presented.     

Studies on well coupled Photosystem I-enriched subchloroplast vesicles. Content and redox properties of electron-transfer components

Stable and well coupled Photosystem (PS) I-enriched vesicles, mainly derived from the chloroplast stroma lamellae, have been obtained by mild digitonin treatment of spinach chloroplasts. Optimal conditions for chloroplast solubilization are established at a digitonin/chlorophyll ratio of 1 ($\text{w}\text{w}$) and a chlorophyll concentration of 0.2 mM, resulting in little loss of native components. In particular, plastocyanin is easily released at higher digitonin/chlorophyll ratios. On the basis of chlorophyll content, the vesicles show a 2-fold enrichment in ATPase, chlorophyll-protein Complex I, P-700, plastocyanin and ribulose-1,5-bisphosphate carboxylase as compared to chloroplasts, in line with the increased activities of cyclic photophosphorylation and PS I-associated electron transfer as shown previously (Peters, A.L.J., Dokter, P., Kooij, T. and Kraayenhof, R. (1981) in Photosynthesis I (Akoyunoglou, G., ed.), pp. 691–700, Balaban International Science Services, Philadelphia). The vesicles have a low content of the light-harvesting chlorophyll-protein complex and show no PS II-associated electron transfer. Characterization of cytochromes in PS I-enriched vesicles and chloroplasts at 25°C and 77 K is performed using an analytical method combining potentiometric analysis and spectrum deconvolution. In PS I-enriched vesicles three cytochromes are distinguished: c-554 (E′₀ = 335 mV), b-559_LP (E′₀ = 32 mV) and b-563 (E′₀ = ? 123 mV); no b-559_HP is present (LP, low-potential; HP, high-potential). Comparative data from PS I vesicles and chloroplasts are consistent with an even distribution of the cytochrome b-563- cytochrome c-554 redox complex in the lateral plane of exposed and appressed thylakoid membranes, an exclusive location of plastocyanin in the exposed membranes and a dominant location of plastoquinone in the appressed membranes. The results are discussed in view of the lateral heterogeneity of redox components in chloroplast membranes.     

The effect of o-phenanthroline on the midpoint potential of the primary electron acceptor of photosystem II.

The primary electron acceptor of Photosystem II has a midpoint oxidation-reduction potential of +95 mV at pH 7.0 in Photosystem II chloroplast fragments prepared by digitonin treatment. The midpoint potential of the acceptor has a pH dependence of -60 mV/pH unit. At concentrations that inhibit oxygen evolution, o-phenanthroline shifts the midpoint potential of the primary acceptor by +70 mV. The shifted potential retains the same dependence on pH. The effect of o-phenanthroline suggests that it interacts directly with the primary electron acceptor of photosystem II in a manner similar to that reported previously for the primary electron acceptor in purple photosynthetic bacteria.