Asymmetry of an energy transducing membrane. The location of cytochrome c2 in Rhodopseudomonas spheroides and Rhodopseudomonas capsulata

Monospecific antibodies have been prepared against cytochrome c₂ from Rhodopseudomonas spheroides and Rhodopseudomonas capsulata, and against cytochrome c′ from Rps. capsulata. These antibodies precipitated their respective antigens, but did not cross react with a wide range of procaryotic or eucaryotic cytochromes, or with other bacterial proteins. The cytochromes produced during aerobic growth were immunologically indistinguishable from those produced during photosynthetic growth.Cytochrome c₂ is located in vivo in the periplasmic space between the cell wall and the cell membrane, and when chromatophores are prepared from whole cells the cytochrome becomes trapped inside these vesicles. The implications of these results to energy coupling in the photosynthetic bacteria are discussed.     

Methoxyspheroidene and methoxyspheroidenone,two carotenoids from Rhodopseudomonas spheroides

Two new carotenoids isolated from Rhodopseudomonas spheroides (Rhodospirillaceae) have been identified as methoxyspheroidene (1,1′-dimethoxy-3,4-didehydro-1,2,1′,2′,7$\text{,}\text{?}$8′-hexahydro-ψ,ψ-carotene) obtained from anaerobic cultures and methoxyspheroidenone (1,1′-dimethoxy-3,4-didehydro-1,2,1′,2′,7′,8′-hexahydro-ψ,ψ-caroten-2-one) recovered from aerobic cultures.     

The branched respiratory system of photosynthetically grown Rhodopseudomonas capsulata

Various respiratory electron transport activities of Rhodopseudomonas capsulata were studied in membrane fragments prepared from photosynthetically grown cells of a parental strain and two terminal oxidase-defective mutant strains. The NADH and succinate oxidase activities of the mutant having a functional $\text{N,N,N}{}^1\text{,N}{}^1\text{-}\text{tetramethyl}\text{-p-}\text{phenylenediamine}$ oxidase, M6, were considerably more sensitive to inhibition by either antimycin A or cyanide than the corresponding activities of the mutant lacking a functional $\text{N,N,N,}{}^1\text{N}{}^1\text{-}\text{tetramethyl}\text{-p-}\text{phenylenediamine}$ oxidase, M7. The parental strain, Z-1, but not the mutants, showed biphasic inhibitory responses of NADH and succinate oxidase activities with either antimycin A or cyanide. In certain reactions no differences in inhibitor susceptibility were found among the strains tested, implying that the pathways involved were unaffected in the mutants. In this category were the actions of rotenone on NADH oxidase, antimycin A on cytochrome $\text{c}$ reductase and, in M6 and Z-1, cyanide on $\text{N,N,N′,N′-}\text{tetramethyl}\text{-p-}\text{phenylenediamine}$ oxidase. These results suggest that the respiratory chain of the parental strain branches at the ubiquinone-cytochrome $\text{b}$ region into two pathways, each branch goes to a distinct terminal oxidase, and either may be blocked independently by genetic mutation.     

Proton uptake and quenching of bacteriochlorophyll fluorescence in Rhodopseudomonas spheroides

The addition of the cyclic cofactor 2,3,5,6-tetramethyl-p-phenylenediamine (diaminodurene) to a suspension of chromatophores of Rhodopseudomonas spheroides causes a light-dependent quenching of bacteriochlorophyll fluorescence. This effect is similar to one observed in chloroplasts and related to proton uptake. It is distinct from the quenching operative through the redox state of the primary electron donor and acceptor, as shown by its sensitivity to uncouplers and ionophorous antibiotics. The quenching is dependent on light intensity and diaminodurene concentration, and has a pH optimum at 7.1 where up to 70% of the fluorescence could be quenched in the presence of 0.33 mM diaminodurene.     

Reaction center preparations of Rhodopseudomonas spheroides: Energy transfer and structure

1.

1. A procedure for the preparation of a reaction center fraction from wild type Rhodopseudomonas spheroides is described. The process involves two subsequent detergent treatments. The particles were purified down to a protein weight of 120000 daltons. They contain little cytochrome and 1.2 moles of ubiquinone per mole of P870. The negative absorption change in the light minus dark difference spectrum is not inconsistent with the assumption that 1 mole of ubiquinone is reduced per mole of photooxidized P870.     

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.     

The ubiquinone homologue of the green mutant of Rhodopseudomonas spheroides

Ubiquinone was isolated from aerobically, semi-aerobically, and photosynthetically grown cells of the green mutant of Rhodopseudomonas spheroides (strain 2.4.1 Ga). The ubiquinone in each case was characterized by its oxidized and reduced absorption spectra and the specific homologue was identified chromatographically. Under all growth conditions ubiquinone-10 was the only homologue found to be present.     

Characteristics of b-type cytochromes in brain microsomes: Comparison with liver microsomes

Biochemical aspects of b-type cytochromes in swine cerebral microsomes were different from those of cytochrome b₅ in liver microsomes, as well as the difference in absorption spectra. First, the kinetic constants, K_m and V_max, in rotenone-insensitive NADH-cytochrome c reductase activity were different from those of liver microsomes, and the activity of cerebral microsomes was higher than that of liver microsomes. Second, midpoint potentials (E_m) of b-type cytochromes in cerebral microsomes were measured and compared with liver microsomal cytochrome b₅. In cerebral microsomes two components of b-type cytochromes were resolved, and showed E_m's of ?30 and +50 mV, respectively, in the presence of 2 mm KCN. On the other hand, the E_m of liver microsomal cytochrome b₅ was ?6 mV. The high-potential component of cerebral microsomal b-type cytochromes was identified as brain-b′₅ [S. Yoshida, T. Yubisui, and M. Takeshita (1983)Biochem. Int. 7, 291–298] and the low-potential component as brain-b₅. The significance of the difference between cerebral and liver microsomal b-type cytochromes was discussed.     

Redox properties of b-type cytochromes in Escherichia coli and rat liver mitochondria and techniques for their analysis

We describe here apparatus and procedures for conducting potentiometric titrations and for analyzing the collected data in terms of the number of components present, their amounts and their midpoint potentials. Using these procedures we have determined the presence of three forms of cytochrome b₁ in Escherichia coli with midpoint potentials at pH 7.1 of about ?50, +110 and +220 mV. We were not able to demonstrate a change in any of these potentials by the addition of phosphate, ATP, or 2,4-dinitrophenol. We have been able to confirm the presence of two forms of cytochrome b in non-energized mitochondria and the apparent conversion of the low-potential component to a new high potential component upon energization of the mitochondria. However we cite further experimental data that question the actual conversion of one form of cytochrome b to another. An alternative interpretation based on our analysis suggests that the high voltage component may be present in a masked form in the non-energized mitochondria.     

Membrane proteins of Rhodopseudomonas spheroides IV. Characterization of chromatophore proteins

Less than 5% of the protein isolated from Rhodopseudomonas spheroides chromatophores (designated Fraction P₁) is insoluble in 2-chloroethanol. Electrophoresis of these proteins on dodecyl sulphate-polyacrylamide gels reveals a gel pattern similar to those obtained from anaerobic and aerobic cell envelope proteins. Chromatophore P₁ is shown to be part of the chromatophore structure and its presence in the chromatophore is not due to contamination from the cytoplasmic membrane.Preparative dodecyl sulphate-polyacrylamide gel electrophoresis was performed to purify chromatophore P_ll proteins, which comprise 95% of the total chromatophore protein. These proteins contain approximately 60–65 mole% non-polar amino acids. Comparison studies of the amino acid compositions, tryptic and chymotryptic maps, molecular weights, and antigenic reactivity of chromatophore proteins demonstrate the existence of protein heterogeneity in chromatophores. These investigations lead us to suggest that chromatophore-specific proteins do not appear in other particulate or soluble fractions derived from either aerobic or anaerobic-grown cells.     

Specificity of the transhydrogenase factor for chromatophores of Rhodopseudomonas spheroides and Rhodospirillum rubrum

Extensive washing of chromatophores of Rhodospirillum rubrum and Rhodopseudomonas spheroides with dilute buffer results in a complete loss of the energylinked transhydrogenase activities of Rsp. rubrum but only a partial loss of the light-driven reaction in chromatophores of Rps. spheroides. It was not possible to reactivate the Rps. spheroides transhydrogenation with the Rsp. rubrum transhydrogenase factor nor with a protein fraction of Rps. spheroides isolated by procedures identical to that used for the isolation of the Rsp. rubrum transhydrogenase factor. The Rsp. rubrum factor is highly specific and cannot be replaced by a number of sulfhydryl compounds tested for reconstitution of Rsp. rubrum transhydrogenation. A published procedure for the isolation of a “transhydrogenase factor” from Rps. spheroides chromatophores yields a preparation having energy-dependent transhydrogenation when supplemented with dithiothreitol in the absence of added chromatophores.     

The absolute quantum efficiency of bacteriochlorophyll photooxidation in reaction centres of Rhodopseudomonas spheroides

The widely assumed correspondence between fluorescence and photochemistry in photosynthetic systems has recently been challenged by observations on the triplet state of bacteriochlorophyll in reaction centres of Rhodopseudomonas spheroides. In order to check this assumption we have conducted a precise determination of the quantum efficiency of bacteriochlorophyll photooxidation in reaction centres at room temperature. We find a quantum efficiency of 1.02 ± 0.04 in contrast to a value of about 0.7 predicted from the variations in fluorescence yield.     

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.     

Electrochromic absorbance changes of photosynthetic pigments in Rhodopseudomonas sphaeroides. I. Stimulation by secondary electron transport at low temperature

Light-induced absorbance changes were measured at temperatures between ?30 and ?55 °C in chromatophores of Rhodopseudomonas sphaeroides. Absorbance changes due to photooxidation of reaction center bacteriochlorophyll (P-870) were accompanied by a red shift of the absorption bands of a carotenoid. The red shift was inhibited by gramicidin D. The kinetics of P-870 indicated electron transport from the “primary” to a secondary electron acceptor. This electron transport was slowed down by lowering the temperature or increasing the pH of the suspension. Electron transport from soluble cytochrome c to P-870⁺ occurred in less purified chromatophore preparations. This electron transport was accompanied by a relatively large increase of the carotenoid absorbance change. This agrees with the hypothesis that P-870 is located inside the membrane, so that an additional membrane potential is generated upon transfer of an electron from cytochrome to P-870⁺.A strong stimulation of the carotenoid changes (more than 10-fold in some experiments) and pronounced band shifts of bacteriochlorophyll B-850 were observed upon illumination in the presence of artificial donor-acceptor systems. Reduced N-methylphenazonium methosulphate (PMS) and N,N,N′,N′-tetramethyl-p-phenylenediamine (TMPD) were fairly efficient donors, whereas endogenous ubiquinone and oxidized PMS acted as secondary acceptor. These results indicate the generation of large membrane potentials at low temperature, caused by sustained electron transport across the chromatophore membrane. The artificial probe, merocyanine MC-V did not show electrochromic band shifts at low temperature.     

Reconstitution of light-dependent electron transport in membranes from a bacteriochlorophyll-less mutant of Rhodopseudomonas spheroides

A mutant, O₁, of Rhodopseudomonas spheroides has been prepared that is not capable of bacteriochlorophyll synthesis, but excretes pigments spectroscopically similar to green plant chlorophylls. The cytochrome content and respiratory activity of membranes from O₁ resemble those of aerobically grown wild type R. spheroides, but the mutant could not adapt to grow photosynthetically. Photosynthetic reaction centres were purified from the blue green mutant, of R. spheroides, added to membranes from O₁, and the detergent used in reaction centre preparation removed by carefully controlled reduction. A reaction centre membrane complex was formed in which the ratio of reaction centre to cytochrome b was near 1 : 2. Illumination caused oxidation of the membrane cytochrome c and reduction of cytochrome b. These changes were enhanced in the presence of antimycin A, suggesting that a cyclic electron flow system had been reconstituted. The implication of these results on the formation of the photosynthetic electron flow system is discussed.     

Effect of pH on cytochromes b in ATP-Mg submitochondrial particles

Addition of ATP to anaerobic, succinate-reduced phosphorylating submitochondrial particles (ATP-Mg particles) causes reduction of cytochromes b absorbing at 558 and 566 nm in the pH range 5.5–9.0. The extent of the reduction of both cytochromes induced by ATP is maximal at pH 7.4–7.5. On the other hand, addition of ATP to anaerobic, NADH-reduced particles causes oxidation of b₅₆₂ at high pH, while it causes reduction of cytochromes absorbing at 558 and 566 nm at low pH. The optimal pH for the oxidation of cytochromes b is in the region 8.5–9.0. Partial reduction of the cytochromes absorbing at 558 and 566 nm can be brought about non-energetically by lowering the potential of the substrate redox couple or by making the reaction mixture alkaline. Addition of the electron-transfer mediator, phenazine methosulphate, to anaerobic, NADH-reduced particles causes complete reduction of cytochromes b absorbing at 558 and 566 nm in the pH range 5.5–9.0. The findings are interpreted in terms of a pH-induced removal of an accessibility barrier (structural or kinetic) that interferes with the redox equilibrium between NADH and cytochrome b.