Ubiquinol regeneration by plasma membrane ubiquinone reductase

Summary Several enzyme systems have been proposed to play a role in the maintenance of ubiquinol in membranes other than the inner mitochondrial membrane. The aim of this study was to investigate the mechanisms involved in NADH-driven regeneration of antioxidant ubiquinol at the plasma membrane. Regeneration was measured by quantifying the oxidized and reduced forms of ubiquinone by electrochemical detection after separation by high-performance liquid chromatography. Plasma membrane incubation with NADH resulted in the consumption of endogenous ubiquinone, and a parallel increase in ubiquinol levels. The activity showed saturation kinetics with respect to the pyridine nucleotides and was moderately inhibited byp-hydroxymercuribenzoate. Only a slight inhibition was achieved with dicumarol at concentrations reported to fully inhibit DT-diaphorase. Salt-extracted membranes displayed full activity of endogenous ubiquinol regeneration, supporting the participation of an integral membrane protein. In liposomes-reconstituted systems, the purified cytochromeb ₅ reductase catalyzed the reduction of the natural ubiquinone homologue coenzyme Q₁₀ at rates accounting for the activities observed in whole plasma membranes, and decreased the levels of lipid peroxidation. Our data demonstrate the role of the cytochromeb ₅ reductase in the regeneration of endogenous ubiquinol.Abbreviations AAPH 2,2-azobis-(2-amidinopropane) hydrochloride - CoQ coenzyme Q, ubiquinone - CoQH₂ reduced coenzyme Q, ubiquinol - pHMB p-hydroxymercuribenzoate     

Sulfide-quinone and sulfide-cytochrome reduction in Rhodobacter capsulatus

The reduction by sulfide of exogenous ubiquinone is compared to the reduction of cytochromes in chromatophores of Rhodobacter capsulatus. From titrations with sulfide values for V_max of 300 and 10 moles reduced/mg bacteriochlorophyll a·h, and for K_m of 5 and 3 M were estimated, for decyl-ubiquinone-and cytochrome c-reduction, respectively. Both reactions are sensitive to KCN, as has been found for sulfide-quinone reductase (SQR) in Oscillatoria limnetica, which is a flavoprotein. Effects of inhibitors interfering with quinone binding sites suggest that at least part of the electron transport from sulfide in R. capsulatus employs the cytochrome bc ₁-complex via the ubiquinone pool.Abbreviations BChl a bacteriochlorophyll a - DAD diaminodurene - decyl-UQ decyl-ubiquinone - LED light emitting diode - NQNO 2-n-nonyl-4-hydroxyquinoline-N-oxide - PQ-1 plastoquinone 1 - SQR sulfide-quinone reductase (E.C. 1.8.5.'.) - UQ ubiquinone 10 - Q_c the quinone reduction site on the cytochrome b ₆ f/bc ₁, complex (also termed Q_i or Q_r or Q_n) - Q_s the quinone reduction site on SQR - Q_z quinol oxidation site on the b ₆ f/bc ₁, complex (also termed Q_o or Q_p)     

Genetic Evidence for Coenzyme Q Requirement in Plasma Membrane Electron Transport

Plasma membranes isolated from wild-type Saccharomyces cerevisiae crude membrane fractions catalyzed NADH oxidation using a variety of electron acceptors, such as ferricyanide, cytochrome c, and ascorbate free radical. Plasma membranes from the deletion mutant strain coq3, defective in coenzyme Q (ubiquinone) biosynthesis, were completely devoid of coenzyme Q₆ and contained greatly diminished levels of NADH–ascorbate free radical reductase activity (about 10% of wild-type yeasts). In contrast, the lack of coenzyme Q₆ in these membranes resulted in only a partial inhibition of either the ferricyanide or cytochrome-c reductase. Coenzyme Q dependence of ferricyanide and cytochrome-c reductases was based mainly on superoxide generation by one-electron reduction of quinones to semiquinones. Ascorbate free radical reductase was unique because it was highly dependent on coenzyme Q and did not involve superoxide since it was not affected by superoxide dismutase (SOD). Both coenzyme Q₆ and NADH–ascorbate free radical reductase were rescued in plasma membranes derived from a strain obtained by transformation of the coq3 strain with a single-copy plasmid bearing the wild type COQ3 gene and in plasma membranes isolated form the coq3 strain grown in the presence of coenzyme Q₆. The enzyme activity was inhibited by the quinone antagonists chloroquine and dicumarol, and after membrane solubilization with the nondenaturing detergent Zwittergent 3–14. The various inhibitors used did not affect residual ascorbate free radical reductase of the coq3 strain. Ascorbate free radical reductase was not altered significantly in mutants atp2 and cor1 which are also respiration-deficient but not defective in ubiquinone biosynthesis, demonstrating that the lack of ascorbate free radical reductase in coq3 mutants is related solely to the inability to synthesize ubiquinone and not to the respiratory-defective phenotype. For the first time, our results provide genetic evidence for the participation of ubiquinone in NADH–ascorbate free radical reductase, as a source of electrons for transmembrane ascorbate stabilization.     

Pigmented basidiomycetous yeasts are a promising source of carotenoids and ubiquinone Q<Subscript>10</Subscript>

Strains of basidiomycetous yeasts isolated from different sources were studied in order to determine the content of carotenoid pigments and ubiquinone Q₁₀ for subsequent selection work to obtain producers of these substances. The high specific productivity of carotenoids (600–700 mg/g) was revealed in the representatives of the following species: Cystofilobasidium capitatum, Rhodosporidium diobovatum, R. sphaerocarpum, Rhodotorula glutinis, Rh. minuta, and Sporobolomyces roseus. The ratio of the major pigments (torulene, torularhodine, and β-carotene) in the representatives of different species was studied. Certain specific features of pigment formation in relation to the taxonomic position of the yeasts were determined. Eurybiont species with substantial ecological lability are the most active producers of carotenoids and ubiquinone Q₁₀ among the epiphytes. It is the first time a comparative analysis of the coenzyme Q₁₀ content in different taxa has been performed using several strains of the same species. The maximal coenzyme Q₁₀ production (1.84 mg/g of dry biomass) was found in the yeast species R. sphaerocarpum.     

Effects of phosphatidylserine on the oxidation of low density lipoprotein

• 1.1. LDL was incubated in the presence of 1 μ M CuSO₄ for 18 hr at 37°C. The content of lipoperoxides was found to be approx. 40 nmol MDA equivalents/mg LDL protein. The addition of 50 μM phosphatidylserine (PS) reduced the content of lipoperoxides to 15% of control values.
• 2.2. The electrophoretic mobility observed for LDL oxidized in the presence of PS approximated the mobility observed for native LDL.
• 3.3. The formation of conjugated dienes was strongly inhibited when LDL was oxidized in the presence of PS.
• 4.4. The addition of 50 μM phosphatidylcholine, phosphatidylglycerol and cardiolipin did not alter the extent of LDL oxidation.
• 5.5. PS did not inhibit the oxidation of LDL mediated by J774 macrophages in the presence of Ham's F-10 culture medium. Under these conditions, PS was found to be an excellent substrate for oxidation.

     

Kinetics of ubiquinone reduction by the resolved succinate: Ubiquinone reductase

A significant lag in the thenoyltrifluoroacetone (TTFA)-sensitive succinate: ubiquinone reductase activity was observed when a ubiquinone-deficient resolved preparation of the enzyme was assayed in the presence of exogenous ubiquinone-2 (Q2) and 2,6-dichlorophenolindophenol. No such lag was seen when the free radical of N,N,N′,N′-tetramethyl-p-phenylenediamine (Wurster's Blue) was used as the terminal electron acceptor, or when the reduction of Q2 was directly measured. The apparent Km value for exogenous Q2 was determined in the Q2-mediated TTFA-sensitive succinate: Wurster's Blue reductase reaction. When the enzyme activity was measured directly by monitoring Q2 reduction without terminal acceptors, the time course of the reaction deviated from zero-order kinetics at Q2 concentrations which were much higher than those expected from the KQ2m value determined in the presence of Wurster's Blue. The time course of Q2 reduction fits a curve describing a competitive interrelationship between oxidized and reduced Q2 at the specific binding site. The data obtained are in agreement with the Q-pool behavior of ubiquinone in mitochondrial membranes and suggest that the rate of ubiquinone reduction by succinate is dependent on the ratio.     

Organization and function of cytochromeb and ubiquinone in the cristae membrane of beef heart mitochondria

The arrangement and function of the redox centers of the mammalianbc ₁ complex is described on the basis of structural data derived from amino acid sequence studies and secondary structure predictions and on the basis of functional studies (i.e., EPR data, inhibitor studies, and kinetic experiments). Two ubiquinone reaction centers do exist—a QH₂ oxidation center situated at the outer, cytosolic surface of the cristae membrane (Q₀ center), and a Q reduction center (Q _i center) situated more to the inner surface of the cristae membrane. The Q₀ center is formed by theb-566 domain of cytochromeb, the FeS protein, and maybe an additional small subunit, whereas the Q _i center is formed by theb-562 domain of cytochromeb and presumably the 13.4kDa protein (QP-C). The Q binding proteins are proposed to be protein subunits of the Q reaction centers of various multiprotein complexes. The path of electron flow branches at the Q₀ center, half of the electrons flowing via the high-potential cytochrome chain to oxygen and half of the electrons cycling back into the Q pool via the cytochromeb path connecting the two Q reaction centers. During oxidation of QH₂, 2H⁺ are released to the cytosolic space and during reduction of Q, 2H⁺ are taken up from the matrix side, resulting in a net transport across the membrane of 2H⁺ per e^– flown from QH₂ to cytochromec, the H⁺ being transported across the membrane as H (H⁺ + e^–) by the mobile carrier Q. The authors correct their earlier view of cytochromeb functioning as a H⁺ pump, proposing that the redox-linkedpK changes of the acidic groups of cytochromeb are involved in the protonation/deprotonation processes taking place during the reduction and oxidation of Q. The reviewers stress that cytochromeb is in equilibrium with the Q pool via the Q _i center, but not via the Q₀ center. Their view of the mechanisms taking place at the reductase is a Q cycle linked to a Q-pool where cytochromeb is acting as an electron pump.     

The regulation of ubiquinone synthesis in fibroblasts: The effect of modulators of β-hydroxy-β-methylglutaryl-coenzyme A reductase activity

The effect of inhibitors of β-hydroxy-β-methylglutaryl-coenzyme A (HMG-CoA) reductase such as low-density lipoprotein (LDL) and compactin were tested for their effects on the biosynthesis of ubiquinone in fibroblasts using [2-¹⁴C]acetic acid as a labeled precursor. LDL added to fibroblasts incubated in lipoprotein-deficient serum inhibited acetate incorporation into ubiquinone by 35%. Compactin, 2.5 μm, inhibited acetate incorporation by 60%. Further increases in compactin concentration up to 20 μm gradually increased the extent of inhibition but leveled off between 70 and 80%. The incorporation of ³H]mevalonic acid and 4-[U-¹⁴C]hydroxybenzoic acid into ubiquinone were determined with a range of compactin concentrations. Whereas the incorporation of [³H]mevalonate showed an apparent increase in response to compactin, the incorporation of 4-[U-¹⁴C]hydroxybenzoate into ubiquinone decreased. Both curves leveled off at concentrations of 5 μm did not significantly change with further increases in compactin concentration approaching 20 μm. Thus, the inhibition of acetate and 4-hydroxybenzoate incorporation into ubiquinone by compactin showed similar patterns. Cells incubated in lipoprotein-deficient serum compared to whole human serum showed inhibition of acetate incorporation similar to that observed previously for 4-hydroxybenzoate (9), thereby suggesting the presence of a stimulatory factor for ubiquinone biosynthesis in whole human serum. These data confirm and extend our earlier conclusions that inhibition of HMG-CoA reductase greatly affects ubiquinone synthesis in fibroblasts.     

Primary Steps in the Energy Conversion Reaction of theCytochrome bc 1 Complex QO Site

The primary energy conversion (Q_O) site of the cytochrome bc ₁ complex is flanked by bothhigh- and low-potential redox cofactors, the [2Fe–2S] cluster and cytochrome b _L, respectively.From the sensitivity of the reduced [2Fe–2S] cluster electron paramagnetic resonance (EPR)spectral g _x-band and line shape to the degree and type of Q_O site occupants, we have proposeda double-occupancy model for the Q_O site by ubiquinone in Rhodobacter capsulatus membranevesicles containing the cytochrome bc ₁ complex. Biophysical and biochemical experimentshave confirmed the double occupancy model and from a combination of these results and theavailable cytochrome bc ₁ crystal structures we suggest that the two ubiquinone molecules inthe Q_O site serve distinct catalytic roles. We propose that the strongly bound ubiquinone,termed Q_OS, is close to the [2Fe–2S] cluster, where it remains tightly associated with the Q_Osite during turnover, serving as a catalytic cofactor; and the weaker bound ubiquinone, Q_OW,is distal to the [2Fe–2S] cluster and can exchange with the membrane Q_pool on a time scalemuch faster than the turnover, acting as the substrate. The crystallographic data demonstratesthat the FeS subunit can adopt different positions. Our own observations show that theequilibrium position of the reduced FeS subunit is proximal to the Q_O site. On the basis of this, wealso report preliminary results modeling the electron transfer reactions that can occur in thecytochrome bc ₁ complex and show that because of the strong distance dependence of electrontransfer, significant movement of the FeS subunit must occur in order for the complex to beable to turn over at the experimental observed rates.     

A water soluble CoQ10 formulation improves intracellular distribution and promotes mitochondrial respiration in cultured cells

Background

Mitochondria are both the cellular powerhouse and the major source of reactive oxygen species. Coenzyme Q₁₀ plays a key role in mitochondrial energy production and is recognized as a powerful antioxidant. For these reasons it can be argued that higher mitochondrial ubiquinone levels may enhance the energy state and protect from oxidative stress. Despite the large number of clinical studies on the effect of CoQ₁₀ supplementation, there are very few experimental data about the mitochondrial ubiquinone content and the cellular bioenergetic state after supplementation. Controversial clinical and in vitro results are mainly due to the high hydrophobicity of this compound, which reduces its bioavailability.

Principal Findings

We measured the cellular and mitochondrial ubiquinone content in two cell lines (T67 and H9c2) after supplementation with a hydrophilic CoQ₁₀ formulation (Qter®) and native CoQ₁₀. Our results show that the water soluble formulation is more efficient in increasing ubiquinone levels. We have evaluated the bioenergetics effect of ubiquinone treatment, demonstrating that intracellular CoQ₁₀ content after Qter supplementation positively correlates with an improved mitochondrial functionality (increased oxygen consumption rate, transmembrane potential, ATP synthesis) and resistance to oxidative stress.

Conclusions

The improved cellular energy metabolism related to increased CoQ₁₀ content represents a strong rationale for the clinical use of coenzyme Q₁₀ and highlights the biological effects of Qter®, that make it the eligible CoQ₁₀ formulation for the ubiquinone supplementation.     

On coenzyme Q orientation in membranes: A linear dichroism study of ubiquinones in a model bilayer

Summary A general approach is developed to interpret linear dichroism (LD) spectra of ubiquinones (Q _n) in host bilayers. Information is reported in terms of guest-host mutual orientation and localization. The overall orientational anisotropy of guest ubiquinone molecules is described by a basic set of limiting orientation/localization modes. Assignments of the UV transitions of the ubiquinone chromophore were obtained by the liquid crystal-linear dichroism technique and molecular orbital (CNDO/S) calculations. The LD spectra of Q _n in the bilayers provided by the lyotropic nematic mesophase exhibited by water solutions of potassium laurate and decanol were interpreted on the basis of the above assignments. The resulting experimental evidence showed a multisite distribution in the host bilayer for the aromatic heads of all the investigated Q _n derivatives except Q₀. The orientational distribution suggested by the LD spectra fits the solubilization model recently proposed by G. Lenaz [J. Membrane Biol. (1988) 104:193–209] for ubiquinone in lipid membranes. Within this model Q _n molecules are located in the midplane and their headgroups oscillate transversally across the membrane. Q ₀ instead has a single site location, close to the polar bilayer interface. Experimental evidence that the headgroup carbonyls tend to grasp the polar interface of the host bilayer was also obtained. Orientation and location distributions of Q _n guest molecules are therefore likely to result from the tendency of their aromatic heads to grasp the polar heads of the host bilayer and from the concurrent tendency of their chains to settle into the hydrocarbon host interior.abbreviations AA average absorption - OD, OD optical densities for plane polarized radiations parallel () and perpendicular () to the sample optical axis - OD OD — OD - EPR electron paramagnetic resonance - LC-LD liquid crystal-linear dichroism - LD linear dichroism - LD _r reduced linear dichroism. - MO molecular orbital - N nematic - NMR nuclear magnetic resonance - S _jj order parameters of the directions j of the transition moments of the guest chromophore - S _ii order parameters of the orientational axes i of the guest molecule with respect to the magnetic field - S _ii order parameters of the axes i of the guest molecules with respect to the bilayer axis a - S _a order parameters of the host bilayer axis a with respect to the orienting magnetic field - _j,i deflection angles between the directions j and the axes i - O _i optical factors of the i axis see Eq. (A4)] - Q_n ubiquinone whose isoprenoid chain contains n isoprenoid units Dr. A. Rossi is gratefully acknowledged for the t.e.m. reduction of the spectra. Ubiquinone homologs were kind gifts from Eisai Co., Tokyo, Japan. This work was supported by M.U.R.S.T., and C.N.R. Target Project on Biotechnology and Bioinstrumentation, Rome, Italy.     

Reaction center light harvesting B875 complexes from Rhodocyclus gelatinosus: characterization and identification of quinones

Reaction center-B875 pigment-protein complexes were purified from Rhodocyclus gelatinosus. The proteic components consist of 7–8 polypeptides among which some were identified by their apparent molecular weights: the light harvesting B875 polypeptides and of 8 and 6 kDa, reaction center L (23 kDa), M (28 kDa) and H (34 kDa), cytochrome c (43 kDa). Four c-type hemes were found per reaction center. Flash-induced absorbance changes showed the presence of both Q_A and Q_B in the complex. Charge recombination times were determined to be: 1.16±0.2 (n=30) for P⁺Q_AQ_B ^- and 7–10 ms for P⁺Q_A ^- in presence of herbicides. From quinone analysis on one hand and kinetics of charge recombination on the other hand, we proposed that in the reaction center of Rhodocyclus gelatinosus Q_A is menaquinone 8 and Q_B is ubiquinone 8.     

Coenzyme Q10 and statins: Biochemical and clinical implications

Statins are drugs of known and undisputed efficacy in the treatment of hypercholesterolemia, usually well tolerated by most patients. In some cases treatment with statins produces skeletal muscle complaints, and/or mild serum CK elevation; the incidence of rhabdomyolysis is very low. As a result of the common biosynthetic pathway Coenzyme Q (ubiquinone) and dolichol levels are also affected, to a certain degree, by the treatment with these HMG-CoA reductase inhibitors. Plasma levels of CoQ₁₀ are lowered in the course of statin treatment. This could be related to the fact that statins lower plasma LDL levels, and CoQ₁₀ is mainly transported by LDL, but a decrease is also found in platelets and in lymphocytes of statin treated patients, therefore it could truly depend on inhibition of CoQ₁₀ synthesis. There are also some indications that statin treatment affects muscle ubiquinone levels, although it is not yet clear to which extent this depends on some effect on mitochondrial biogenesis. Some papers indicate that CoQ₁₀ depletion during statin therapy might be associated with subclinical cardiomyopathy and this situation is reversed upon CoQ₁₀ treatment. We can reasonably hypothesize that in some conditions where other CoQ₁₀ depleting situations exist treatment with statins may seriously impair plasma and possible tissue levels of coenzyme Q₁₀. While waiting for a large scale clinical trial where patients treated with statins are also monitored for their CoQ₁₀ status, with a group also being given CoQ₁₀, physicians should be aware of this drug-nutrient interaction and be vigilant to the possibility that statin drugs may, in some cases, impair skeletal muscle and myocardial bioenergetics.     

Effect of ubiquinone 50 and viral infection on phytohemagglutinin activity in development of induced resistance in tobacco plants

The effects of ubiquinone 50 (synthetic coenzyme Q₁₀) and viral infection on phytohemagglutinin activity were studied in the tobacco (Nicotiana tabacum L.) cultivar Samsun NN, which carries the necrosis-formation locus and exhibits hypersensitivity to tobacco mosaic virus (TMV) and ubiquinone (Q₁₀). The treatment with Q₁₀ and inoculation with TMV were accompanied by an increase in phytohemagglutinin activity, indicating that lectins may be involved in the development of defense responses in plants.     

Fluvastatin depresses the enhanced lipid peroxidation in vitamin E-deficient hamsters

Fluvastatin, a 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor, has recently been reported to have the antioxidative activity in vitro. However, it is still unclear whether chronic treatment with this drug actually leads to amelioration of the redox status in the body. In this study, we investigated the antioxidative effect of fluvastatin in vivo, using a vitamin E-deficient hamster model, an in vivo model of enhanced oxidative stress. After pre-treatment with a vitamin E-deficient diet for 2 months, fluvastatin, pravastatin or probucol was added to the diet for 1 month. Vitamin E deficiency caused a significant increase in the levels of plasma oxidative stress markers such as 8-iso-prostaglandin F2α (8-iso-PGF2α) and hydroperoxides. Furthermore, there was a significant increase in the oxidizability of plasma lipids in the vitamin E-deficient animals, indicating that the oxidative stress was increased in the circulation. Fluvastatin markedly depressed the above oxidative stress markers in plasma, and significantly decreased the oxidizability of plasma lipids without affecting their levels. Probucol, a reference antioxidant, also showed a similar effect while pravastatin, another HMG-CoA reductase inhibitor, showed only a weak improvement. We suggest that the treatment with fluvastatin leads to a reduction of oxidative stress in vivo, which is mainly derived from its antioxidative property rather than its lipid-lowering activity.     

Redox status and pharmacokinetics of coenzyme Q10 in rat plasma after its single intravenous administration

The pharmacokinetics of the total pool of coenzyme Q₁₀ (CoQ₁₀), its oxidized (ubiquinone) and reduced (ubiquinol, CoQ₁₀H₂) forms have been investigated in rats plasma during 48 h after a single intravenous injection of a solution of solubilized CoQ₁₀ (10 mg/kg) to rats. Plasma levels of CoQ₁₀ were determined by HPLC with spectrophotometric and coulometric detection. In plasma samples taken during the first minutes after the CoQ₁₀ intravenous injection, the total pool of coenzyme Q₁₀ and proportion of CoQ₁₀H₂ remained unchanged during two weeks of storage at ?20°C. The kinetic curve of the total pool of coenzyme Q₁₀ corresponds to a one-compartment model (R ₂ = 0.9932), while the corresponding curve of its oxidized form fits to the two-compartment model. During the first minutes after the injection a significant portion of plasma ubiquinone undergoes reduction, and after 7 h the concentration of ubiquinol predominates. The decrease in total plasma coenzyme Q₁₀ content was accompanied by the gradual increase in plasma ubiquinol, which represented about 90% of total plasma CoQ₁₀ by the end of the first day. The results of this study demonstrate the ability of the organism to transform high concentrations of the oxidized form of CoQ₁₀ into the effective antioxidant (reduced) form and justify prospects of the development of parenteral dosage forms of CoQ₁₀ for the use in the treatment of acute pathological conditions.     

Fluorescence characteristics of photoautotrophic soybean cells

We report here the first measurements on chlorophyll (Chl) a fluorescence characteristics of photoautotrophic soybean cells (cell lines SB-P and SBI-P). The cell fluorescence is free from severe distortion problems encountered in higher plant leaves. Chl a fluorescence spectra at 77 K show, after correction for the spectral sensitivity of the photomultiplier and the emission monochromator, peaks at 688, 696 and 745 nm, representing antenna systems of photosystem II-CP43 and CP47, and photosystem I, respectively. Calculations, based on the complementary area over the Chl a fluorescence induction curve, indicated a ratio of 6 of the mobile plastoquinone (including Q_B) to the primary stable electron acceptor, the bound plastoquinone Q_A. A ratio of one between the secondary stable electron acceptor, bound plastoquinone Q_B, and its reduced form Q_B ^- was obtained by using a double flash technique. Owing to this ratio, the flash number dependence of the Chl a fluorescence showed a distinct period of four, implying a close relationship to the S state of the oxygen evolution mechanism. Analysis of the Q_A ^- reoxidation kinetics showed (1) the halftime of each of the major decay components ( 300 s fast and 30 ms slow) increases with the increase of diuron and atrazine concentrations; and (2) the amplitudes of the fast and the slow components change in a complementary fashion, the fast component disappearing at high concentrations of the inhibitors. This implies that the inhibitors used are able to totally displace Q_B. In intact soybean cells, the relative amplitude of the 30 ms to 300 s component is higher (40:60) than that in spinach chloroplasts (30:70), implying a larger contribution of the centers with unbound Q_B. SB-P and SBI-P soybean cells display a slightly different sensitivity of Q_A ^- decay to inhibitors.Abbreviations CA complementary area over fluorescence induction curve - Chl chlorophyll, diuron - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - F _m maximum chlorophyll a fluorescence - F ₀ minimum chlorophyll a fluorescence - F _v = F _t-F₀ - where F _v = variable chlorophyll a fluorescence - and F_t = chlorophyll a fluorescence at time t - PS II photosystem II - Q _a primary (plastoquinone) electron acceptor of PS II - Q _b secondary (plastoquinone) electron acceptor of PS II - t₅₀ the time at which the concentration of reduced Q _a is 50% of that at its maximum value     

How rapid are the internal reactions of the ubiquinol:cytochrome c 2 oxidoreductase?

The temperature dependence of the partial reactions leading to turn-over of the UQH₂:cyt c ₂ oxidoreductase of Rhodobacter sphaeroides have been studied. The redox properties of the cytochrome components show a weak temperature dependence over the range 280–330 K, with coefficients of about 1 m V per degree; our results suggest that the other components show similar dependencies, so that no significant change in the gradient of standard free-energy between components occurs over this temperature range. The rates of the reactions of the high potential chain (the Rieske iron sulfur center, cytochromes c ₁ and c ₂, reaction center primary donor) show a weak temperature dependence, indicating an activation energy < 8 kJ per mole for electron transfer in this chain. The oxidation of ubiquinol at the Q_z-site of the complex showed a strong temperature dependence, with an activation energy of about 32 kJ mole^–1. The electron transfer from cytochrome b-566 to cytochrome b-561 was not rate determining at any temperature, and did not contribute to the energy barrier. The activation energy of 32 kJ mole^–1 for quinol oxidation was the same for all states of the quinone pool (fully oxidized, partially reduced, or fully reduced before the flash). We suggest that the activation barrier is in the reaction by which ubiquinol at the catalytic site is oxidized to semiquinone. The most economical scheme for this reaction would have the semiquinone intermediate at the energy level indicated by the activation barrier. We discuss the plausibility of this simple model, and the values for rate constants, stability constant, the redox potentials of the intermediate couples, and the binding constant for the semiquinone, which are pertinent to the mechanism of the ubiquinol oxidizing site.Abbreviations (BChl)₂ P870, primary donor of the photochemical reaction center - b/c ₁ complex ubiquinol: cytochrome c ₂ oxidoreductase - cyt b _H cytochrome b-561 or higher potential cytochrome b - cyt b _L cytochrome b-566, or low potential cytochrome b - cyt c ₁, cyt c ₂, cyt c _t cytochromes c ₁ and c ₂, and total cytochrome c (cyt c ₁ and cyt c ₂) - Fe.S Rieske-type iron sulfur center, Q - QH₂ ubiquinone, ubiquinol - Q_z, Q_zH₂, Q_z ^– ubiquinone, ubiquinol, and semiquinone anion of ubiquinone, bound at quinol oxidizing site - Q_z-site ubiquinol oxidizing site (also called Q_o-(outside) - Q_o (Oxidizing) - Q_P (Positive proton potential) site) - Q_c-site uubiquinone reductase site (also called the Q_i-(inside) - Q_R (Reducing), or - Q_N (Negative proton potential) site) - UHDBT 5-(n-undecyl)-6-hydroxy-4,7-dioxobenzothiazol     

Vectorial electron transport in Degulfovibrio vulgaris (Marburg) growing on hydrogen plus sulfate as sole energy source

Desulfovibrio vulgaris (Marburg) was grown on hydrogen plus sulfate as sole energy source in a medium containing excess iron. The topography of electron transport components was investigated. The bacterium contained per mg cells (dry weight) 30U hydrogenase (1U=1 mol/min), 35 g desulfoviridin (= bisulfite reductase), 0.6 U adenosine phosphosulfate reductase, 30 mU thiosulfate reductase, 0.3 nmol cytochrome c ₃ (M _r=13,000), 0.04 nmol cytochrome b, 0.85 nmol menaquinone, and 0.4 nmol ferredoxin. Hydrogenase (>95%) and cytochrome c ₃ (82%) were localized on the periplasmic side and desulfoviridin (95%), adenosine phosphosulfate reductase (87%), thiosulfate reductase (74%), and ferredoxin (71%) on the cytoplasmic side of the cytoplasmic membrane; menaquinone and cytochrome b were exlusively found in the membrane fraction. The location of the oxidoreductases indicate that in D. vulgaris (Marburg) H₂ oxidation and sulfate reduction take place on opposite sides of the cytoplasmic membrane rather than on the same side, as has recently been proposed.     

The circadian rhythm in Bryophyllum leaves: Phase control by radiant energy

An inactivated nitrate reductase (EC 1.6.6.1) formed in vivo by the green alga Chlorella fusca Shihira and Kraus is shown to be a cyanide complex. The partially purified inactive enzyme releases 0.048 nmol of HCN per unit of enzyme activated. This compares with 0.066 nmol of HCN liberated in similar previous measurements with the inactivated enzyme from Chlorella vulgaris. The nitrate reductase from C. fusca has been purified to a level of 67 mol nitrate reduced per min per mg enzyme. It contains a cytochrome b₅₅₇, at a level 1.9-fold higher per unit of active enzyme, than the nitrate reductase from C. vulgaris.Abbreviations FAD flavin-adenine dinucleotide - NADH nicotineamide-adenine-dinucleotide (reduced)