Effect of the side chain structure of coenzyme Q on the steady state kinetics of bovine heart NADH: coenzyme Q oxidoreductase

Steady state kinetics of bovine heart NADH: coenzyme Q oxidoreductase using coenzyme Q with two isoprenoid unit (Q₂) or with a decyl group (DQ) show an ordered sequential mechanism in which the order of substrate binding and product release is NADH-Q₂ (DQ) -Q₂H₂ (DQH₂)-NAD⁺ in contrast to the order determined using Q₁ (Q₁-NADH-NAD⁺-Q₁H₂) (Nakashima et al., J. Bioenerg. Biomembr. 34, 11–19, 2002). The effect of the side chain structure of coenzyme Q suggests that NADH binding to the enzyme results in a conformational change, in the coenzyme Q binding site, which enables the site to accept coenzyme Q with a side chain significantly larger than one isoprenoid unit. The side chains of Q₂ and DQ bound to the enzyme induce a conformational change in the binding site to stabilize the substrate binding, while the side chain of Q₁ (one isoprenoid unit) is too short to induce the conformational change.     

Ubiquinone system of the form-genusChrysosporium

The ubiquinone (coenzyme Q: Q) system of 17 strains of the form-genusChrysosporium was analyzed by high performance liquid chromatography (HPLC) and found to show a heterogeneous distribution of the major ubiquinone. Q-9, Q-10 or Q-10(H₂) was found to be the major ubiquinone in 3, 9 and 5 strains, respectively. It was further demonstrated that the teleomorphs of the species characterized by Q-9 and Q-10 could be classified into two separate families, Arthrodermataceae (Q-9) and Onygenaceae (Q-10), which were defined within the revised order Onygenales by Currah. Teleomorphs ofChrysosporium species having Q-10(H₂) have not been found. This paper also includes the ubiquinone system of dermatophytes which relate to the form-genusChrysosporium morphologically.     

Ubiquinone systems in fungi. V. Distribution and taxonomic implications of ubiquinones in Eurotiales, Onygenales and the related plectomycete genera, except for Aspergillus, Paecilomyces, Penicillium, and their related teleomorphs

The ubiquinone (coenzyme Q) systems were determined for 176 teleomorphic isolates, 14 anamorphic isolates, and three samples of fruit-bodies of Dendrosphaera eberhardtii, which belonged to Eurotiales, Onygenales, and related taxa. In Eurotiales, Ascosphaera had Q-9, whereas Bettsia had Q-10. All isolates of Monascaceae had the Q-10 system, whereas those of four genera of Pseudeurotiaceae had the Q-10(H₂) system. The Q-10(H₂) system was found in genera of Trichocomaceae, except for Aspergillus, Penicillium, Paecilomyces, and their related taxa. However, Thermoascus had the Q-9 system. In Onygenales, members of Arthrodermataceae had Q-9, and those of Gymnoascaceae had Q-10(H₂). Isolates of Myxotrichaceae were characterized by Q-10(H₂) with few exceptions, which had Q-10. The quinones of Onygenaceae belonged to complex systems, i.e., Q-9, 0-10 and 0-10(H₂), and a combination of two systems. Families Onygenaceae and Trichocomaceae are likely a phylogenetic heterogeneity. Ubiquinone analysis provides a very useful criterion of great promise for classifying eurotialean taxa and also for identifying their isolates.     

A durohydroquinone oxidation site in the mitochondrial transport chain

Although duroquinone had little effect upon NADH oxidation in neutral lipid depleted mitochondria, durohydroquinone was oxidized by ETP at a rate sensitive to antimycin A. Fractionation of mitochondria into purified enzyme systems showed durohydroquinone: cytochromec reductase to be concentrated in NADH: cytochromec reductase, absent in succinate:cytochromec reductase, and decreased in reduced coenzyme Q:cytochromec reductase. Durohydroquinone oxidation could be restored by recombining reduced coenzyme Q:cytochromec reductase with NADH:coenzyme Q reductase. Pentane extraction had no effect upon either durohydroquinone or reduced coenzyme Q₁₀ oxidation, indicating lack of a quinone requirement between cytochromesb andc. Both chloroquine diphosphate and acetone (96%) treatment irreversibly inhibited NADH but not succinate oxidation. Neither reagents had any effect upon durohydroquinone oxidation but both inhibited reduced coenzyme Q₁₀ oxidation 50%, indicating a site of action between Q₁₀ and duroquinone sites. Loss of chloroquine sensitive reduced coenzyme Q₁₀ oxidation after acetone extraction suggests two sites for Q₁₀ before cytochromeb.     

Studies on reduced and oxidized coenzyme Q (ubiquinones). II. The determination of oxidation-reduction levels of coenzyme Q in mitochondria,microsomes and plasma by high-performance liquid chromatography

Reduced and oxidized coenzyme Q₁₀ (Q₁₀H₂ and Q₁₀) in guinea-pig liver mitochondria were rapidly extracted and determined by high-performance liquid chromatography (HPLC). The percentages of Q₁₀H₂ as compared to the total (sum of Q₁₀ and Q₁₀H₂) were increased by the addition of respiratory substrates such as succinate, malate and β-hydroxybutyrate (State 4). The levels of Q₁₀H₂ in State 4 were increased more extensively with electron-transport inhibitors such as KCN, NaN₃ and antimycin A. These results indicate that the method for determining Q₁₀H₂ and Q₁₀ by HPLC is quite useful for investigation of the physiological function of coenzyme Q in mitochondria and other organelles. The reduced and oxidized coenzyme Q levels of rat liver mitochondria, which contain both coenzyme Q₉ and coenzyme Q₁₀, were measured simultaneously. The results suggest that coenzymes Q₉ and Q₁₀ play a similar role as an electron carriers. The liver microsomes of guinea-pig contained approx. 133 nmol total coenzyme Q₁₀ per g protein. The Q₁₀H₂ levels of microsomes were increased from 46.5 to 67.5 and 64.8% with NADH and NADPH, respectively. The plasma levels of total coenzyme Q were 0.92 μg/ml for man, 0.35 μg/ml for guinea-pig and 0.27 μg/ml for rat. The reduced coenzyme Q were also present in those plasma samples. The levels of reduced coenzyme Q were 51.1, 48.9 and 65.3%, respectively.     

The coenzyme Q system in the classification of the ascosporogenous yeast genus Dekkera and the asporogenous yeast genus Brettanomyces

Fourteen strains of the genera Dekkera and Brettanomyces were examined for the coenzyme Q system. Without exception they contained the Q-9 system. The results are discussed from the taxonomic point of view.     

Effect of coenzyme Q10 supplementation on cardiac hypertrophy of male rats consuming a high-fructose,low-copper diet

Administration of coenzyme Q₁₀ to humans and animals has a beneficial effect on a number of cardiac diseases. The purpose of the present study was to determine if coenzyme Q₁₀ treatment could ameliorate cardiac abnormalities associated with the carbohydrate × copper interaction in rats. Weanling male rats were provided with a copper-deficient diet (0.6 μg Cu/g) containing either 62.7% starch (S−Cu) or fructose (F−Cu) for 5 wk. Half of the rats provided with the F−Cu diet were given daily oral supplements of 300 mg coenzyme Q₁₀/kg body weight (F−Cu+Q). Heart hypertrophy, liver enlargement, or pancreatic atrophy were not affected by, nor was body growth or anemia improved by, supplementation with coenzyme Q₁₀ when compared to rats fed only the F−Cu diet. Hearts from rats fed the F−Cu diet had severe inflammation, degeneration, fibrosis, and giant mitochondria with abnormal cristae. Hearts from F−Cu+Q rats had similar mitochondrial changes as the F−Cu rat hearts but without any apparent degenerative changes. None of the F−Cu+Q rats, but 30% of the F−Cu rats, died during the study as a result of heart rupture. These observations show that whereas coenzyme Q₁₀ treatment did not prevent the cardiac hypertrophy of the carbohydrate × copper interaction, it did play a role in maintaining the integrity of the heart. This work was presented in part at the 2nd International Symposium on Metal Ions in Biology and Medicine, Loutraki, Greece, May 15–22, 1992 (Metal Ions (1992), J. Anastassopoulou, P. Collery, J.C. Etienne, T. Theophanides, eds., John Libbey Eurotext, Montrouge, France, pp. 402–407).     

A conserved START domain coenzyme Q-binding polypeptide is required for efficient Q biosynthesis,respiratory electron transport,and antioxidant function in Saccharomyces cerevisiae

Coenzyme Q_n (ubiquinone or Q_n) is a redox active lipid composed of a fully substituted benzoquinone ring and a polyisoprenoid tail of n isoprene units. Saccharomyces cerevisiae coq1–coq9 mutants have defects in Q biosynthesis, lack Q₆, are respiratory defective, and sensitive to stress imposed by polyunsaturated fatty acids. The hallmark phenotype of the Q-less yeast coq mutants is that respiration in isolated mitochondria can be rescued by the addition of Q₂, a soluble Q analog. Yeast coq10 mutants share each of these phenotypes, with the surprising exception that they continue to produce Q₆. Structure determination of the Caulobacter crescentus Coq10 homolog (CC1736) revealed a steroidogenic acute regulatory protein-related lipid transfer (START) domain, a hydrophobic tunnel known to bind specific lipids in other START domain family members. Here we show that purified CC1736 binds Q₂, Q₃, Q₁₀, or demethoxy-Q₃ in an equimolar ratio, but fails to bind 3-farnesyl-4-hydroxybenzoic acid, a farnesylated analog of an early Q-intermediate. Over-expression of C. crescentus CC1736 or COQ8 restores respiratory electron transport and antioxidant function of Q₆ in the yeast coq10 null mutant. Studies with stable isotope ring precursors of Q reveal that early Q-biosynthetic intermediates accumulate in the coq10 mutant and de novo Q-biosynthesis is less efficient than in the wild-type yeast or rescued coq10 mutant. The results suggest that the Coq10 polypeptide:Q (protein:ligand) complex may serve essential functions in facilitating de novo Q biosynthesis and in delivering newly synthesized Q to one or more complexes of the respiratory electron transport chain.     

Coordinated, coenzyme Q reversible, 2,5-dibromothymoquionine inhibition of electron transport and ATPase in Escherichia coli.

2,6-dibromothymoquinone (DBMIB) and other coenzyme Q analogs partially inhibit electron transport and the membrane-bound Mg⁺⁺ stimulated ATPase of $\text{E. coli}$ membranes. The inhibitions by DBMIB are fully reversed by coenzyme Q₆, and other analogs show partial reversal by coenzyme Q₆. Electron transport reactions inhibited are NADH and lactate oxidase, NADH menadione reductase, lactate phenazinemethosulfate reductase and duroquinol oxidase. The concentrations of DBMIB required are similar for electron transport and ATPase inhibition and inhibitions are all increased by uncouplers. Electron transport and ATPase are not inhibited in a DBMIB insensitive mutant. Soluble ATPase extracted from the membranes does not show DBMIB inhibition under either high or low Mg⁺⁺ conditions. Lipophilic chelators show additional inhibition over DBMIB. It appears that coenzyme Q functions at three sites in $\text{E. coli}$ electron transport where ATPase activity is controlled. Coenzyme Q deficient mutants also show decreased electron transport and ATPase activity which is restored by coenzyme Q.     

Coenzyme Q systems in ascomycetous black yeasts

72 Strains belonging to 44 species of ascomycetous black yeasts were analyzed for their coenzyme Q systems. Prevalent were Q-10 and dihydrogenated Q-10 systems. Members of the Dothidealean suborder Dothideineae have Q-10 (H₂), while those belonging to the suborder Pseudosphaeriineae mostly have Q-10. The anamorph genus Exophiala Carmichael and the teleomorph genus Capronia Sacc. seem to be heterogenous.     

Comparison of growth stimulation of HeLa cells,HL-60 cells,and mouse fibroblasts by coenzyme Q10

Summary The addition of coenzyme Q₁₀ to culture media stimulates the serum-free growth of HeLa, HL-60 cells, and mouse fibroblasts (Balb/3T3). With HeLa cells, the stimulation by coenzyme Q₁₀ is additive to the stimulation by ferricyanide, an impermeable electron acceptor for the transplasma membrane electron transport. This combined response to coenzyme Q₁₀ and ferricyanide is enhanced with insulin. -Tocopherylquinone can also stimulate the growth of HeLa cells, but vitamin K₁ is inactive. Specificity of quinone effects is indicated. Serum-free growth of Balb/3T3 and SV 40 transformed BaIb/3T3 (SV/T2) cells is also stimulated by coenzyme Qio with stimulation similar to HeLa cells. However, Balb/3T3 cells are not stimulated by ferricyanide, which does not increase the response to coenzyme Q₁₀. The transformed cells (SV/T2) respond better to ferricyanide alone, but the effects of coenzyme Qio and ferricyanide are not additive. Serum-free growth of HL-60 cells is stimulated dramatically by coenzyme Q₁₀. The extent of growth stimulation on HL-60 cells is almost six-fold that of HeLa or Balb/3T3 cells. The stimulation of NADH-ferricyanide reductase (a transmembrane redox enzyme) by coenzyme Q₁₀ with HL-60 cells is similar to their growth pattern in response to coenzyme Q₁₀. Unlike HL-60, HeLa and Balb/3T3 cells show little stimulation of ferricyanide reduction by coenzyme Q₁₀. The stimulatory effect on both ferricyanide reduction and cell growth by the short side-chain coenzyme Q₂ is much less than that of the long side-chain coenzyme Q₁₀. Ferricyanide reduction by HeLa cells is inhibited by coenzyme Q analogs such as 2,3-dimethoxy-5-chloro-6-naphthyl-mercapto-coenzyme Q and 2-methoxy-3-ethoxyl-5-methyl-6-hexadecyl-mercapto-coenzyme Q. However, these inhibitions are reversed by coenzyme Q₁₀. The growth inhibition of HL-60 cells by other coenzyme Q analogs, such as capsiacin can also be reversed by coenzyme Q₁₀. These data indicate that plasma membrane-based NADH oxidation or modification of the membrane quinone redox balance may be a basis for the growth stimulation.     

Orientation of complex III in the yeast mitochondrial membrane: Labeling with [125I] diazobenzenesulfonate and functional studies with the decyl analogue of coenzyme Q as substrate

Mitochondria (or mitoplasts) and submitochondrial particles from yeast were treated with [¹²⁵I] diazobenzenesulfonate to label selectively proteins exposed on the outer or inner surface of the inner mitochondrial membrane. Polyacrylamide gel analysis of the immunoprecipitates formed with antibodies against Complex III or cytochromeb revealed that the two core proteins and cytochromeb were labeled in both mitochondria and submitochondrial particles, suggesting that these proteins span the membrane. Cytochromec ₁ and the iron sulfur protein were labeled in mitochondria but not in submitochondrial particles, suggesting that these proteins are exposed on the cytosolic side of the inner membrane. The steady-state reduction of cytochromesb andc ₁ was determined with succinate and the decyl analogue of coenzyme Q as substrates. Addition of the coenzyme Q analogue to mitochondria caused reduction of 15–30% of the total dithionite-reducibleb and 100% of the cytochromec ₁: Addition of the coenzyme Q analogue to submitochondrial particles led to the reduction of 70% of the total dithionite-reducible cytochromeb but insignificant amounts of cytochromec ₁. A model to explain the topography of Complex III in the inner membrane is proposed based on these results.Abbreviations used: DABS, diazobenzene sulfonate; DBH₂, reduced form of decyl analogue of coenzyme Q (2,3-dimethoxy-5-methyl-6-n-decyl-1,4-benzoquinone); PMSF, phenylmethylsulfonyl fluoride; SDS, sodium dodecyl sulfate.     

Distribution of ubiquinones (coenzyme Q) in Gram negative bacillae]

The coenzyme Q system was examined on 55 strains of Gram negative aerobic or facultatively anaerobic rods. No bacteria contain Co-Q7 nor Co-Q10. Ubiquinone Q8 predominates in Flavobacterium and in Enterobacteriaceae; Q9 was the only homolog found in the Pseudomonas, and predominates in the Acinetobacter.     

On the Partly Reduced Coenzyme Q Isolated from “Rhodotorula lactose” IFO 1058 and Its Relation to the Taxonomic Position

From the intact cells of “Rhodotorula lactosa” R1 (IFO 1058), a new coenzyme Q, which has a different mobility on paper chromatograms from other five naturally occurring homologs of the coenzyme Q series, was isolated and purified as a crystalline state. The chemical analyses such as UV and IR absorption spectrophotometries, and NMR and mass spectrometries revealed that the material, mp 28.7~28.9°C, was identified as a Co Q₁₀ derivative with the reduced C₅ unit in the isoprenoid side chain terminal remote from the quinone nucleus, Co Q₁₀ (H–10). The strain R 1 with such a unique coenzyme Q system is, concerning its taxonomic position, discussed in connection with other criteria.     

The thermotropic properties of coenzyme Q10 and its lower homologues

The thermotropic properties of coenzymes Q₁₀, Q₉, Q₈, and Q₇ have been examined by differential scanning calorimetry and wide-angle X-ray diffraction. Typical scanning calorimetry cooling curves of coenzyme Q from the liquid state exhibit a single exothermic phase transition into a crystalline state at a temperature that decreases as the length of the polyisoprenoid side-chain substituent decreases. Upon subsequent heating, the molecules undergo a series of thermal events which precede the main crystalline-to-liquid endothermic phase transition. The temperature of these transitions increases with increasing chain length. The crystallization phase transition temperature depends markedly on the rate at which the sample is cooled and increases with decreasing scan rate; the temperature of the melting endotherm is not markedly affected by the scan rate. Detailed calorimetric studies of coenzyme Q₁₀ indicate that two crystalline states are formed, one at relatively high cooling rates to low temperatures and the other when preparations are cooled slowly from the liquid state to relatively high temperatures. Heating the crystalline phase formed by rapid cooling causes its transformation into the phase observed by cooling slowly. X-ray diffraction analysis confirmed the existence of these two crystal phases in coenzymes Q₉ and Q₁₀ and the transformation from the rapidly crystallized form to the more ordered form associated with slower cooling rates. At body temperature (310 K) under equilibrium conditions coenzyme Q₁₀ exists in an ordered crystalline phase; the implications of the thermotropic behavior of coenzyme Q₁₀ on mitochondrial functionin vitro andin vivo are discussed.     

The second coenzyme Q1 binding site of bovine heart NADH: coenzyme Q oxidoreductase

The rotenone sensitivity of bovine heart NADH: coenzyme Q oxidoreductase (Complex I) depends significantly on coenzyme Q₁ concentration. The rotenone-insensitive Complex I reaction in Q₁ concentration range above 300 M indicates an ordered sequential mechanism with Q₁ and reduced Q₁ (Q₁H₂) as the initial substrate to bind to the enzyme and the last product to be released from the enzyme product complex, respectively. This is the case in the rotenone-sensitive reaction although both K _m and V _max values of the rotenone-insensitive reaction for Q₁ are significantly higher than those of the rotenone-sensitive reaction (Nakashima et al., 2002, J. Bioenerg. Biomemb. 34, 11–19). This rigorous control mechanism between the nucleotide and ubiquinone binding sites strongly suggests that the rotenone-insensitive reaction is also physiologically relevant.     

Steady-State Kinetics of NADH:coenzyme Q Oxidoreductase Isolated from Bovine Heart Mitochondria

Steady-state kinetics of the bovine heart NADH:coenzyme Q oxidoreductase reaction were analyzed in the presence of various concentrations of NADH and coenzyme Q with one isoprenoid unit (Q₁). Product inhibitions by NAD⁺ and reduced coenzyme Q₁ were also determined. These results show an ordered sequential mechanism in which the order of substrate binding and product release is Q₁–NADH–NAD⁺–Q₁H₂. It has been widely accepted that the NADH binding site is likely to be on the top of a large extramembrane portion protruding to the matrix space while the Q₁ binding site is near the transmembrane moiety. The rigorous controls for substrate binding and product release are indicative of a strong, long range interaction between NADH and Q₁ binding sites.     

The site of inhibition of mitochondrial electron transfer by coenzyme Q analogues.

The effects of 33 quinone derivatives on mitochondrial electron transfer in yeast were examined. Twenty-two of the compounds were also tested for their effects on the growth of yeast cells. Four strong inhibitors of electron transfer were identified: 5-n-undecyl-6-hydroxy-4, 7-dioxobenzothiazole, 7-ω-cyclohexyloctyl-6-hydroxy-5,8-quinolinequinone, 7-n-hexadecyl-mercapto-6-hydroxy-5, 8-quinolinequinone, and 3-n-dodecylmercapto-2-hydroxy-1, 4-naphthoquinone. They inhibit the growth of yeast with ethanol as an energy source, but not when glucose is the energy source. The NADH oxidase activity of isolated mitochondria is 50% inhibited by these quinone derivatives at about 10^?8m, or 0.5 μmol/g mitochondrial protein; 1000-fold higher concentrations do not affect electron transfer from NADH or succinate to coenzyme Q₂. The effects of the inhibitors on cytochrome spectra indicate that they block electron transfer between cytochromes b and c₁. A possible antagonism between these compounds and coenzyme Q at a site between cytochromes b and C₁ is discussed in terms of Mitchell's “protonmotive Q cycle” hypothesis (Mitchell, P. (1976) J. Theor. Biol. 62, 327–367). 6-β-naphthylmercapto-5-chloro-2,3-dimethoxy-1,4-benzoquinone inhibits electron transfer between succinate and coenzyme Q₂ or phenazine methosulfate, suggesting a site in the succinate-coenzyme Q reductase complex with a different quinone specificity from that of the site in the cytochrome bc₁ complex. Seven of the quinone derivatives inhibit growth on both glucose and ethanol media, indicating that their effect is not the result of inhibition of respiration.     

The function of water channels in Chara: The temperature dependence of water and solute flows provides evidence for composite membrane transport and for a slippage of small organic solutes across water channels

Using the cell pressure probe, the effects of temperature on hydraulic conductivity (Lp; osmotic water permeability), solute permeability (permeability coefficient, P_s), and reflection coefficients (σ_s) were measured on internodes of Chara corallina, Klein ex Willd., em R.D.W.. For the first time, complete sets of transport coefficients were obtained in the range between 10 and 35 °C which provided evidence about pathways of water and solutes as they move across the plasma membrane (water channel and bilayer arrays). Test solutes used to check for the selectivity of water channels were monohydric alcohols of different molecular size and shape (ethanol, n-propanol, iso-propanol, and tert-butanol) and heavy water (HDO). Within the limits of accuracy, Q₁₀ values for Lp and for the diffusive water permeability (P_d) were identical (Q₁₀ for Lp = 1.29 ± 0.17 (± SD; n = 15 cells) and Q₁₀ for P_d = 1.25 ± 0.16 (n = 5 cells)). The Q₁₀ values were equivalent to activation energies of E_a = 16.8 ± 6.4 and 16.6 ± 10.0 kJ · mol⁻¹, respectively, which is similar to that of self-diffusion or of viscous flow of water. The Q₁₀ values and activation energies for P_s of the alcohols were significantly larger (ethanol: Q₁₀ = 1.68 ± 0.16, E_a = 37.1 ± 5.9 kJ · mol⁻¹; n-propanol: Q₁₀ =  1.75 ± 0.40, E_a = 43.1 ± 15.3 kJ · mol⁻¹; iso-propanol: Q₁₀ = 2.12 ± 0.42, E_a =  52.2 ± 14.6 kJ · mol⁻¹; tert-butanol: Q₁₀ = 2.13 ± 0.56, E_a = 51.6 ± 17.1 kJ · mol⁻¹; ±SD; n = 5 to 6 cells). Effects of temperature on reflection coefficients were most pronounced. With increasing temperature, σ_s values of the alcohols decreased and those of HDO increased. The data indicate that water and solutes use different pathways when crossing the membrane. Ordinary and isotopic water use water channels and the other test solutes use the bilayer array (composite transport model of membrane). Changes in σ_s values with temperature were found to be a sensitive measure for the open/closed state of water channels. The decrease of σ_s with temperature was theoretically predicted from the temperature dependence of P_s and Lp. Differences between predicted and measured values of σ_s allowed estimation of the bypass flow (slippage) of solutes through water channels which did not completely exclude test solutes. The permeability of channels depended on the structure and size of test solutes. It is concluded that water channels are much less selective than is usually thought. Since water channels represent single-file or no-pass pores, solutes drag along considerable amounts of water as they diffuse across channels. This results in low overall values of σ_s. The σ_s of HDO was extremely low. Its response to temperature was opposite to that for the σ_s of the alcohols. This suggested a stronger effect of temperature on the hydraulic (osmotic) than on the diffusive water flow across individual water channels, i.e. a differential sensitivity of different mechanisms to temperature. Received: 10 October 1996 / Accepted: 2 December 1996     

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.