Inhibition of autoxidation of egg yolk phosphatidylcholine in homogenous solution and in liposomes by oxidized ubiquinone

The aim of this study was to obtain a quantification of the antioxidant activity of ubiquinone. To this purpose the oxidation of egg yolk phosphatidylcholine both in solvent and in liposomes initiated by an azocompound has been studied either in the absence or in the presence of ubiquinone-3, using alpha-tocopherol as a reference antioxidant. The two experimental systems gave similar results. In the presence of ubiquinone-3 the oxidation rate was reduced with respect to control experiments but was faster than that in the presence of alpha-tocopherol. The amount of ubiquinone required to decrease the autoxidation rate was so high as to prevent detection of the induction period. The stoichiometric factor was greater than 2 and the rate constant of inhibition was two orders of magnitude lower than that of alpha-tocopherol. It is concluded that high concentrations of ubiquinone are required to exhibit significant antioxidant activity. A possible mechanism compatible with the stoichiometric factor larger than 2 for the inhibiting effect of ubiquinone is also suggested.     

On the mechanism of inhibition of NADH oxidase by ubiquinone-3

The combined effects of rotenone and ubiquinone-3 on the kinetics of NADH dehydrogenase and NADH oxidase have been investigated. The two inhibitors do not show additivity; on the other hand, ubiquinone-3, when preincubated with the enzyme, partially removes rotenone sensitivity. The inhibition of NADH oxidase by ubiquinone-3 is the result of at least two combined effects: the competition of the less active ubiquinone-3 with endogenous ubiquinone-10 in the acceptor site of the dehydrogenase, and a nonspecific action on the structure of complex I. The latter effect is perhaps mediated by a physical change of the phospholipid bilayer similar to that observed with agents such as butanol, perturbing lipid-protein interactions in the membrane.     

Identification of ubiquinone-50 as the major methylated nonpolar lipid in human monocytes. Regulation of its biosynthesis via methionine-dependent pathways and relationship to superoxide production

Human blood monocytes incorporated the methyl group from methionine into their neutral lipids. The major methylated product was identified as ubiquinone-50 in monocytes, lymphocytes, and a variety of human tumor cell lines by several analytical procedures including TLC or high performance liquid chromatography and as ubiquinone-45 in a mouse tumor cell line. Up to three methyl groups were shown to be derived from methionine by mass spectrometry. The rate of synthesis of ubiquinone-50 by monocytes as assessed by measuring labeled methyl group incorporation was shown to be linear over a 3-h period. Degradation of ubiquinone proceeded slowly; 80% of the labeled compound persisted after 18 h. The dependence of ubiquinone-50 synthesis upon methionine concentration was established in monocytes, with an estimated apparent Km for methionine of about 20 microM. The tumor promoter, tetradecanoate phorbol acetate, a potent stimulator of superoxide anion (O2-) production in phagocytic cells, inhibited ubiquinone-50 synthesis at nanomolar concentrations in monocytes, but not in lymphocytes, under conditions where oxidation of methionine takes place. Degradation of the labeled ubiquinone was unaffected. Formylmethionylleucyl-phenylalanine, a chemoattractant peptide which stimulates O2- production in phagocytic cells, also inhibited ubiquinone-50 synthesis. The degree of inhibition by either stimulus was increased when the methionine concentration in the medium was low. These findings demonstrate that in human monocytes ubiquinone-50 biosynthesis is regulable and that methionine concentration modulates both its rate of synthesis and the inhibitory effects of two stimuli of O2- production.     

Synthesis of ubiquinone and cholesterol in human fibroblasts: regulation of a branched pathway.

The current studies demonstrate that cultured human flbroblasts utilize mevalonate for the synthesis of ubiquinone-10 as well as for the synthesis of cholesterol. Study of the regulation of this branched pathway was facilitated by incubating the cells with compactin (ML-236B), a competitive inhibitor of 3-hydroxy-3-methylglutaryI coenzyme A reductase, which blocked the formation of mevalonate within the cell. The addition of known amounts of [³H]mevalonate to the culture medium in the presence of compactin permitted the study of the relative rates of mevalonate incorporation into cholesterol and ubiquinone-10 under controlled conditions. When low concentrations of exogenous [³H]mevalonate (10 to 50 μm) were added to cells that were provided with exogenous cholesterol in the form of plasma low density lipoprotein (LDL), the cells incorporated the [³H]mevalonate into ubiquinone-10 at a rate that was two- to threefold faster than the incorporation into cholesterol. When the cells were deprived of exogenous LDL-cholesterol, the incorporation of [³H]mevalonate into ubiquinone-10 decreased and the incorporation of [³H]mevalonate into cholesterol increased. As a result, in the absence of exogenous cholesterol more than 60 times as much [³H]mevalonate was incorporated into cholesterol as into ubiquinone-10. Considered together with previous findings, the current data are compatible with a regulatory mechanism in which LDL inhibits cholesterol synthesis in fibroblasts at two points: (1) at the level of 3-hydroxy-3-methylglutaryl coenzyme A reductase, thereby inhibiting mevalonate synthesis, and (2) at one or more points distal to the last intermediate common to the cholesterol and ubiquinone-10 biosynthetic pathways. The latter inhibition allows ubiquinone-10 synthesis to continue in the presence of LDL despite a 98% reduction in mevalonate synthesis.     

Antioxidative effect of ubiquinones on mitochondrial membranes.

Peroxidation of mitochondria occurs extensively in ubiquinone-depleted membranes. Reincorporation into the membranes of either the physiological ubiquinone or a short-chain homologue protects mitochondria against peroxidation. The ability to prevent this phenomenon is more evident in mitochondria that have incorporated ubiquinone-3 and might be ascribed to an ordering structural effect on the lipid bilayer.     

The recognition of a special ubiquinone functionally central in the ubiquinone-cytochrome b-c2 oxidoreductase.

Although the energy conserving membranes of the photosynthetic bacterium Rhodopseudomonas sphaeroides contain a 25 (+/- 3)-fold molar excess of ubiquinone over the photochemical reaction center, the activity of the ubiquinone-cytochrome b-c2 oxidoreductase is unaffected by quinone extraction until only 3, or at most 4, ubiquinones remain; only then does further extraction prevent the function of the oxidoreductase. Since 2 of these last ubiquinones are integral parts of the photochemical reaction center, we conclude that the ubiquinone-cytochrome b-c2 oxidoreductase requires only 1, or at most 2, molecules of ubiquinone-10 for its function. Earlier kinetic data identified a major electron donor to ferricytochrome c2 as a single molecule (known as Z) which requires 2 electrons and 2 protons for its equilibrium reduction. Hence, we identify a single molecule of quinone, probably ubiquinone-10 in a special environment, as a major electron donor to ferricytochrome c2 in the ubiquinone cytochrome b-c2 oxidoreductase.     

The mode of action of lipid-soluble antioxidants in biological membranes: relationship between the effects of ubiquinol and vitamin E as inhibitors of lipid peroxidation in submitochondrial particles.

The effects of ubiquinol and vitamin E on ascorbate- and ADP-Fe3+-induced lipid peroxidation were investigated by measuring oxygen consumption and malondialdehyde formation in beef heart submitochondrial particles. In the native particles, lipid peroxidation showed an initial lag phase, which was prolonged by increasing concentrations of ascorbate. Lipid peroxidation in these particles was almost completely inhibited by conditions leading to a reduction of endogenous ubiquinone, such as the addition of succinate or NADH in the presence of antimycin. Lyophilization of the particles followed by three or four consecutive extractions with pentane resulted in a complete removal of vitamin E and a virtually complete removal of ubiquinone, as revealed by reversed-phase high pressure liquid chromatography. In these particles, lipid peroxidation showed no significant lag phase and was not inhibited by either increasing concentrations of ascorbate or conditions leading to ubiquinone reduction. Treatment of the particles with a pentane solution of vitamin E (alpha-tocopherol) restored the lag phase and its prolongation by increasing ascorbate concentrations. Treatment of the extracted particles with pentane containing ubiquinone-10 resulted in a restoration of the inhibition of lipid peroxidation by succinate or NADH in the presence of antimycin, but not the initial lag phase or its prolongation by increasing concentrations of ascorbate. Malonate and rotenone, which prevent the reduction of ubiquinone by succinate and NADH, respectively, abolished, as expected, the inhibition of the initiation of lipid peroxidation in both native and ubiquinone-10-supplemented particles. Reincorporation of both vitamin E and ubiquinone-10 restored both effects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activity of reduced ubiquinone: Cytochrome c oxidoreductase with various ubiquinol-isoprenologues as substrate and corresponding inhibitory effect of antimycin in yeast

1. Reduced ubiquinones-1, -2, -3, -4 and -6 were used as substrates for ubiquinol: cytochrome c oxidoreductase.2. The portion of antimycin-sensitive activity depends on the concentration of ubiquinol and on the pH. Only reduced ubiquinone-2 and reduced ubiquinone-3 show high activities the main part of which is sensitive to antimycin.3. The antimycin effect curve of ubiquinol: cytochrome c oxidoreductase is linear in shape with reduced ubiquinone-2 as substrate but sigmoidal with reduced ubiquinone-3 and succinate. Ubiquinol-3: cytochrome c oxidoreductase activity contains a portion scarcely affected by antimycin. About 300 pmoles of antimycin per mg protein, enough to inhibit succinate, NADH- and reduced ubiquinone-2:cytochrome c oxidoreductase almost totally, affect ubiquinol-3: cytochrome c oxidoreductase to only about 80% and another 300 pmoles of antimycin are needed for the next 10% of inhibition.4. The activities of succinate- and NADH: cytochrome c oxidoreductase are stimulated by ubiquinones-2 and -3. The shapes of the inhibition curves by antimycin of the stimulated activities are sigmoidal. About twice the amount of antimycin is necessary to inhibit stimulated activities to the same value as the unstimulated.5. The non-ionic detergent Lubrol WX is not effective in stimulating enzymatic activities. However, in the presence of 0.6 M sorbitol, it converts the linear antimycin effect curve with reduced ubiquinone-2 as substrate, into sigmoidal.6. NADH- and succinate: cytochrome c oxidoreductase activities and reduced ubiquinone-2 and reduced ubiquinone-3: cytochrome c oxidoreductase activities become deactivated with increasing concentrations of the non-ionic detergent Lubrol WX. The activity with reduced ubiquinone-2 as substrate is less resistant to the action of the detergent than with reduced ubiquinone-3. The b-cytochromes do not become CO-reactive by this treatment.7. Deoxycholate in low concentrations does not stimulate ubiquinol: cytochrome c oxidoreductase activity. It converts the inhibition curve by antimycin from sigmoidal to linear with increasing concentrations of the detergent with all substrates tested. The amount of antimycin needed for 90% inhibition of reduced ubiquinone activities is about the same under these conditions as with succinate, NADH or reduced ubiquinol in untreated particles.8. The results are discussed with respect to the theories of the electron transport mechanism and of the inhibition by antimycin of the electron flow through the bc₁-segment of the respiratory chain in beef heart.     

Therapeutic effect of vegetable oils and ubiquinone-9 on radiation injuries

The comparison was made of the protective (the administration 3 h before irradiation with a dose of 7.3 Gy) and therapeutic (the administration immediately and later after exposure) effects of soya oil (150 mg/kg) and oil solution of ubiquinone-9 (100-200 mg/kg) on survival of exposed rats. It was shown that soya oil and ubiquinone-9 increased the survival rate of rats when administered before and, to a lesser extent, immediately after irradiation. Corn oil administered immediately after exposure increased the survival rate as well. DMF for the therapeutic effect of soya oil solution of ubiquinone-9 was 1.08.     

Production of ubiquinone-10 using bacteria

Among the bacterial strains known to contain ubiquinone-10, three strains, Agrobacterium tumefaciens KY-3085 (ATCC4452), Paracoccus denitrificans KY-3940 (ATCC19367) and Rhodobacter sphaeroides KY-4113 (FERM-P4675), were selected as excellent producers of this ubiquinone. The ubiquinone-10 production by the Agrobacterium and Rhodobacter strains was affected by aeration. An ethionine-resistant mutant (M-37) derived from A. tumefaciens KY-3085 promoted increased production of ubiquinone-10 (20% higher than the parent). Another Agrobacterium mutant (AU-55), which was induced by the successive addition of four genetic markers, showed a tolerance to the suppression of ubiquinone-10 production caused by aeration, and the fermentation time for production was remarkably shortened. The amount of ubiquinone-10 produced by this Agrobacterium mutant reached 180 mg/l in a 58 h culture. A green mutant (carotenoid-deficient mutant, Co-22-11) derived from R. sphaeroides KY-4113 produced 350 mg/l of ubiquinone-10 under culturing conditions with a limited supply of air, the ubiquinone-10 content being 8.7 mg/g-dry cell. In this case, the amount and content corresponded to 2.8 and 3.6 times larger than those given by the wild-type strain, respectively. A multiple-layer structure of cell membrane was observed in the highly ubiquinone-10 accumulating cell of the green mutant by electron microscopy. The amount of ubiquinone-10 produced by P. denitrificans was much lower than those of the other two strains.     

HQNO-sensitive NADH:quinone oxidoreductase of Bacillus cereus KCTC 3674

The enzymatic properties of NADH:quinone oxidoreductase were examined in Triton X-100 extracts of Bacillus cereus membranes by using the artificial electron acceptors ubiquinone-1 and menadione. Membranes were prepared from B. cereus KCTC 3674 grown aerobically on a complex medium and oxidized with NADH exclusively, whereas deamino-NADH was determined to be poorly oxidized. The NADH oxidase activity was lost completely by solubilization of the membranes with Triton X-100. However, by using the artificial electron acceptors ubiquinone-1 and menadione, NADH oxidation could be observed. The activities of NADH:ubiquinone-1 and NADH:menadione oxidoreductase were enhanced approximately 8-fold and 4-fold, respectively, from the Triton X-100 extracted membranes. The maximum activity of FAD-dependent NADH:ubiquinone-1 oxidoreductase was obtained at about pH 6.0 in the presence of 0.1M NaCl, while the maximum activity of FAD-dependent NADH:menadione oxidoreductase was obtained at about pH 8.0 in the presence of 0.1 M NaCl. The activities of the NADH:ubiquinone-1 and NADH:menadione oxidoreductase were very resistant to such respiratory chain inhibitors as rotenone, capsaicin, and AgNO(3), whereas these activities were sensitive to 2-heptyl-4-hydroxyquinoline-N-oxide (HQNO). Based on these results, we suggest that the aerobic respiratory chain-linked NADH oxidase system of B. cereus KCTC 3674 possesses an HQNO-sensitive NADH:quinone oxidoreductase that lacks an energy coupling site containing FAD as a cofactor.     

Ubiquinone content of eight plant species in cell culture

Crystals of ubiquinone-10 were isolated from soyabean, peanut and Ruta cell cultures, while crystals of ubiquinone-9 were obtained from rice and wheat cell cultures. These crystals also contained lesser amounts of lower and higher homologues (ubiquinone-7 to 10). The ubiquinone content of eight higher plants in cell culture was determined. Ubiquinone-9 content of rice was 680 μg per g dry wt, and this was 3–6 times higher than that of the other plants.     

Half-life of ubiquinone-9 in rat tissues.

The half-life of ubiquinone-9 in various rat tissues was determined. Rats were injected intraperitoneally with [3H]mevalonate and the decay of radioactivity incorporated into ubiquinone-9 was followed using reverse-phase HPLC. The half-life varied between 49 h (testis) and 125 h (kidney).     

The role of ubiquinone in the respiratory chain of Acetobacter xylinum

1. Whole cells of Acetobacter xylinum were found to contain a quinone of the ubiquinone (coenzyme Q) group. The quinone was isolated from the cells and crystallized. It was identified by its physical, chemical and spectroscopic properties as a ubiquinone with 10 isoprene units (ubiquinone-10). No naphthaquinone was detected in the cells. 2. Cell-free extracts prepared by means of a French pressure cell were separated into three fractions by differential centrifugation. The ubiquinone was located predominantly in the particulate fraction sedimenting at 33000g, which also contained most of the NADH oxidase and malate oxidase activities. The concentration of ubiquinone-10 in extracts was similar to that of the flavoproteins and about three times the concentration of the individual cytochromes. 3. Aerobic incubations of crude extracts with either NADH or malate resulted in reduction of the endogenous ubiquinone-10 to steady-state concentrations of 55 and 40% of the total quinone respectively. In the presence of cyanide more than 95% of the endogenous ubiquinone-10 was reduced by either NADH or malate. 4. The initial rate of reduction of endogenous ubiquinone-10 by malate and the rate of ubiquinol oxidation, in A. xylinum extracts, were found to be compatible with the overall rate of malate oxidation with oxygen. 5. The effects of various respiratory inhibitors on the oxidation-reduction reactions of the endogenous quinone indicate that its position on the respiratory chain is between the malate flavoprotein dehydrogenase and the cytochrome chain.     

Effect of oxygen free radicals on ubiquinone in aqueous solution and phospholipid vesicles

The purpose of this study was to evaluate the direct effect of oxygen free radicals produced by ultrasonic irradiation on ubiquinone and to compare the efficiency with which the antioxidant can compete with these radicals when it is both in aqueous solution and within the lipid bilayer. The main product obtained after insonation of aqueous solutions of ubiquinone-0 was ubiquinol, moreover some degradation occurred. The direct electron donor responsible for most of the ubiquinol generated by ultrasonic irradiation appeared to be superoxide radical. Addition reactions of hydroxyl radicals with aromatic ring structure led probably to degradation products of ubiquinone, which were not identified. Experiments were also performed to evaluate the efficiency with which ubiquinone-3 could react with oxygen radicals when it was within the lipid bilayer. The effect of presence or absence of a net surface charge was studied selecting a suitable bilayer including dimyristylphosphatidic acid or stearylamine in uncharged dimyristylphosphatidylcholine vesicles. In these systems hydroxyl radicals did not represent a potential danger for the antioxidant, the reaction between superoxide and ubiquinone-3 instead was significant only in positively charged membranes and gave rise to ubiquinol. It is suggested that ubiquinone acts as an antioxidant by stopping the propagation reaction.     

Reduction of ubiquinone-1 by ascorbic acid is a catalytic and reversible process controlled by the concentration of molecular oxygen

SUMMARY

To address whether reduction by vitamin C may contribute to the in vivo maintenance of coenzyme Q in the reduced form, we studied the reduction of ubiquinone-1 by ascorbate at pH 7.4. Addition of ascorbate to ubiquinone-1 resulted in rapid O₂ consumption and an increase in the steady-state concentration of ascorbyl radical. The initial rate of O₂ consumption was proportional to the product of [ubiquinone-1] and [ascorbate] whereas [ascorbyl radical] was proportional to the square root of this parameter; both dependencies were in quantitative agreement with each other. The extent of O₂ consumption greatly exceeded the amounts of ubiquinone-1 initially present. Formation of ubiquinol-1 from ubiquinone-1 by ascorbate was reversible, moderate under aerobic conditions, but substantial in the absence or near absence of oxygen. At high O₂ concentration, ascorbate promoted the oxidation of ubiquinol-1 to ubiquinone-1. Addition of sodium dodecyl sulphate dramatically decreased the rate of reaction between ubiquinone-1 and ascorbate, most likely as a result of phase separation of the reagents. A preliminary reaction scheme with putative rate constants for the relevant reactions is presented that quantitatively describes the kinetic behaviour of the process studied. The key reactions in the scheme are electron transfer from ascorbate to ubiquinone-1 with formation of the ascorbyl and ubisemiquinone radical. The reaction of the latter with O₂ is postulated to be responsible for O₂ consumption, with ubiquinone-1 acting as a catalyst. Together, the results demonstrate that the extent of reduction of ubiquinone-1 by ascorbate was controlled by the O₂ concentration and the physical availability of the reactants. As the O₂ concentration in human blood is relatively high and ubiquinone-10 is located exclusively within the lipid phase of lipoproteins where negatively charged ascorbate has little access, our results suggest that direct reduction by ascorbate is unlikely to be responsible for the high reduction percentage observed for plasma coenzyme Q.     

Untersuchungen zur Anreicherung von Ergosterol und Ubichinonen aus Lipid-Kohlenwasserstoff-Fraktionen

Adsorption on Silicagel was used for the enrichment of ergosterol and ubiquinone-9 from a lipid-hydrocarbon extract. The main components of the lipid-hydrocarbon extract were hydrocarbons of gas oil (B. p. 513 to 653 K)phosphatides, glycerides, and fatty acids. By adsorption on silicagel (1 part silicagel to 2–3 parts of lipid-hydrocarbon extract dissolved in hexane) were ergosterol and ubiquinone-9 enriched and nearly completely separarated from hydrocarbons and phosphatides, partly from glycerides and fatty acids. Ergosterol and ubiquinone-9 can be obtained by a simplified separation from the enriched fraction.     

The effects of lipid phase transitions on the interaction of mitochondrial NADH--ubiquinone oxidoreductase with ubiquinol--cytochrome c oxidoreductase.

1. The endogenous phosphatidylcholine and phosphatidylethanolamine of Complexes I and III from bovine heart mitochondria may be completely replaced with 1,2-ditetradecanoyl-sn-glycero-3-phosphocholine with at least partial retention of activity. 2. The lipid-replaced enzymes associate in 1:1 molar ratio to give a Complex I--III unit catalysing NADH-cytochrome c oxidoreductase activity. 3. On increasing the concentration of ubiquinone-10 and the synthetic phospholipid, the lipid-replaced Complexes appear to operate independently of each other as in the natural membrane. Thus the lipid-replaced enzymes associate in exactly the same ways as the enzymes containing natural phospholipids. 4. Arrhenius plots of NADH--cytochrome c oxidoreductase activity reconstituted from lipid-replaced Complexes I and III exhibit changes in slope at 24 degrees C. When the concentrations of phospholipid and ubiquinone-10 are increased, the Arrhenius plots show discontinuities at 24 degrees C as well as changes in slope. 5. The kinetics of cytochrome b reduction by NADH were measured in mixtures containing 2 mol of Complex III/mol of Complex I. When the enzymes contained natural phospholipids. the reduction kinetics were biphasic. When the enzymes had been supplemented with further phospholipid and ubiquinone-10 the kinetics were monophasic. When lipid-replaced enzymes were supplemented with 1,2-ditetradecanoyl-sn-glycero-3-phosphocholine and ubiquinone-10, reduction of cytochrome b was monophasic above the phase-transition temperature of the lipid but biphasic below it. 6. These findings are interpreted in terms of the model for the interaction of Complexes in the natural membrane proposed by Heron, Ragan & Trum-power [(1978) Biochem. J. 174, 791--800].     

Participation of chlorobiumquinone in the transplasma membrane electron transport system of Leishmania donovani promastigote: effect of near-ultraviolet light on the redox reaction of plasma membrane

The respiratory quinone composition of the parasitic protozoa Leishmania donovani promastigote was investigated. 1'-oxomenaquinone-7, a chlorobiumquinone was found to be the major isoprenoid quinone. Substantial level of ubiquinone-9 was also present. Isolation and identification of the quinone from the purified plasma membrane yielded mainly 1'-oxomenaquinone-7 and ubiquinone-9; menaquinone was not detected. Membrane bound 1'-oxomenaquinone-7 could be destroyed by near-ultraviolet irradiation, with a concomitant loss or stimulation of plasma membrane electron transport activities. The abilities of different quinones to restore alpha-lipoic acid and ferricyanide reductase activity in near UV-irradiated cell preparations were compared. The order was; conjugate of chlorobiumquinone and sphingosine base approximately conjugate of 2-methyl-3-(1'-oxooctadecyl)-1,4-napthoquinone and octadecylamine > chlorobiumquinone approximately 2-methyl-3-(1'-oxooctadecyl)-1,4-napthoquinone > menaquinone-4 approximately ubiquinone-10. After irradiation with near-UV light, transmembrane alpha-lipoic acid reduction was inhibited, while transmembrane ferricyanide reduction was stimulated. The result obtained indicates that chlorobiumquinone mediates the plasma membrane electron transport between cytosolic reductant and oxygen as well as alpha-lipoic acid. UV-inactivation of chlorobiumquinone shuts down the plasma membrane oxygen uptake and diverts the electron flux towards ferricyanide reduction via ubiquinone-9. Chlorobiumquinone is the only example of a polyisoprenoid quinone containing a side chain carbonyl group from photosynthetic green-sulphur bacteria. Recent work has revealed numerous genes of trypanosomatid sharing common ancestry with plants and/or bacteria. These observations pose some fascinating questions about the evolutionary biology of this important group of parasitic protozoa.     

Function of Ubiquinone in Electron Transport from Reduced Nicotinamide Adenine Dinucleotide to Nitrate and Oxygen in Aerobacter aerogenes

The possible role of quinones in the electron transport system of Aerobacter aerogenes was investigated. The only quinone found in measurable amounts in bacteria grown in minimal media under both aerobic and anaerobic conditions was ubiquinone-8. Membrane-bound ubiquinone-8 could be removed by extraction with pentane, or destroyed by ultraviolet irradiation, with a concomitant loss of both reduced nicotinamide adenine dinucleotide (NADH) oxidase and NADH-linked respiratory nitrate reductase activity. In the extracted membrane preparations, these enzymatic activities could be restored, both to the same degree, by incorporation of ubiquinone-6, -8, or -10, but not by incorporation of menaquinones. The NADH oxidation and the nitrate reduction were sensitive to the respiratory inhibitors dicoumarol, lapachol, and cyanide. The results obtained indicate that ubiquinone-8 mediates the electron transport between NADH and oxygen as well as between NADH and nitrate. Branching of the electron transport chain to oxygen and nitrate occurs after an initial common pathway.