Interaction of positively charged ubiquinone analog (MitoQ10) with DT-diaphorase from liver mitochondria

Effects of the coenzyme Q analog (MitoQ₁₀) carrying a positively charged decyltetraphenylphosphonium group on functional activity of phosphorylating liver mitochondria were studied. Using inhibitory analysis it was found that at micromolar concentrations this quinone is reduced by NADH-dependent DT-diaphorase. Under conditions of malate oxidation, MitoQ₁₀ stimulates electron transfer from NADH to oxygen by shunting the block of rotenone-induced electron transport in Complex I. Steady-state mitochondrial respiration induced by rotenone and MitoQ₁₀ (1 μM), as well as K3 shunt are both blocked by the DT-diaphorase inhibitor dicumarol, the Complex III inhibitor myxothiazole, and the cytochrome oxidase inhibitor cyanide. The electron transport chain induced in liver mitochondria by MitoQ₁₀ in the presence of rotenone appears as follows: NADH → DT-diaphorase → MitoQ₁₀ → Complex III → Complex IV → O₂. Under conditions of malate (but not succinate) oxidation, MitoQ₁₀ and high concentrations of vitamin K3 induce in mitochondria cyanide-resistant respiration and opening of the nonspecific pore eventually resulting in inhibition of oxidative phosphorylation. It is concluded that MitoQ₁₀ should be regarded as an analog of hydrophilic quinones (vitamin K3, duroquinone, etc.) widely known as substrates for mitochondrial DT-diaphorase not interacting with CoQ₁₀ rather than as a natural CoQ₁₀ analog.     

On the sidedness of the ubiquinone redox cycle. Kinetic studies in mitochondrial membranes

The inhibition of NADH oxidation but not of succinate oxidation by the low ubiquinone homologs UQ-2 and UQ-3 is not due to a lower rate of reduction of ubiquinone by NADH dehydrogenase: experiments in submitochondrial particles and in pentane-extracted mitochondria show that UQ-3 is reduced at similar rates using either NADH or succinate as substrates. The fact that reduced UQ-3 cannot be reoxidized when reduced by NADH but can be reoxidized when reduced by succinate may be explained by a compartmentation of ubiquinone.Using reduced ubiquinones as substrates of ubiquinol oxidase activity in intact mitochondria and in submitochondrial particles we found that ubiquinol-3 is oxidized at higher rates in submitochondrial particles than in mitochondria. The initial rates of ubiquinol oxidation increased with increasing lengths of isoprenoid side chains in mitochondria, but decreased in submitochondrial particles. These findings suggest that the site of oxidation of reduced ubiquinone is on the matrix side of the membrane; reduced ubiquinones may reach their oxidation site in mitochondria only crossing the lipid bilayer: the rate of diffusion of ubiquinol-3 is presumably lower than that of ubiquinol-7 due to the differences in hydrophobicity of the two quinones.     

Regulation of Alternative Pathway Activity in Plant Mitochondria : Deviations from Q-Pool Behavior during Oxidation of NADH and Quinols

External NADH and succinate were oxidized at similar rates by soybean (Glycine max) cotyledon and leaf mitochondria when the cytochrome chain was operating, but the rate of NADH oxidation via the alternative oxidase was only half that of succinate. However, measurements of the redox poise of the endogenous quinone pool and reduction of added quinones revealed that external NADH reduced them to the same, or greater, extent than did succinate. A kinetic analysis of the relationship between alternative oxidase activity and the redox state of ubiquinone indicated that the degree of ubiquinone reduction during external NADH oxidation was sufficient to fully engage the alternative oxidase. Measurements of NADH oxidation in the presence of succinate showed that the two substrates competed for cytochrome chain activity but not for alternative oxidase activity. Both reduced Q-1 and duroquinone were readily oxidized by the cytochrome oxidase pathway but only slowly by the alternative oxidase pathway in soybean mitochondria. In mitochondria isolated from the thermogenic spadix of Philodendron selloum, on the other hand, quinol oxidation via the alternative oxidase was relatively rapid; in these mitochondria, external NADH was also oxidized readily by the alternative oxidase. Antibodies raised against alternative oxidase proteins from Sauromatum guttatum cross-reacted with proteins of similar molecular size from soybean mitochondria, indicating similarities between the two alternative oxidases. However, it appears that the organization of the respiratory chain in soybean is different, and we suggest that some segregation of electron transport chain components may exist in mitochondria from nonthermogenic plant tissues.     

Action of halothane upon mitochondrial respiration

The inhibitory action of halothane upon respiration was studied with rat liver mitochondria (RLM³), beef heart mitochondria (HBHM), and electron-transport particles (ETP). With intact mitochondrial preparations the oxidation of NADH-linked substrates but not of succinate was markedly suppressed by low concentrations of halothane (<2 mm as determined by gas-liquid chromatography). This inhibitory action of halothane was completely reversible. In contrast, a number of other mitochondrial processes were found to be sensitive in an irreversible manner at higher concentrations of the anesthetic. Likewise, the oxidation of added NADH by HBHM, ETP, and detergent-disrupted RLM was found to be sensitive in a reversible manner to low concentrations of halothane. The energy-dependent transfer of electrons from succinate to NAD by ETP_H was also sensitive to halothane. On the other hand, the NADH-ferricyanide reductase and the succinic oxidase activities of ETP and the NADH-cytochrome c reductase activity of microsomes were all insensitive to halothane. The site of inhibition by halothane appears to be in the vicinity of the rotenone-sensitive site of complex I (NADH-CoQ reductase). A number of other general anesthetics inhibited respiration at or near the same site as halothane.     

The site of inhibition of dibromothymoquinone in mitochondrial respiration

Dibromothymoquinone (2,5-dibromo, 6-isopropyl, 3-methyl benzoquinone, DBMIB) is a quinone analogue recently introduced as a specific inhibitor of chloroplast photosynthesis at the level of plastoquinone. In beef heart mitochondria DBMIB inhibits the oxidation of both succinate and NAD linked substrates; the apparent K_I is 6 μM for βhydroxybutyrate oxidation and 61μM for succinate oxidation respectively. In sonic fragments NADH oxidation is also inhibited; however, the rotenone block of respiration can be partially bypassed by the autooxidation of reduced DBMIB. Under the same conditions succinoxidase of ETP is inhibited, as in intact mitochondria; autoxidation of DBMIB reduced by succinate can however be obtained in presence of detergents. Hexahydrocoenzyme Q₄ reverses the DBMIB inhibition of succinate in sonic fragments. The site of inhibition by DBMIB is the oxygen side of CoQ, since DBMIB can function as electron acceptor in the NADH-CoQ assay for site I energization in submitochondrial particles, studied by measuring the quenching of atebrin fluorescence.     

On the mechanism of action of polyether XXVIII at site I of the electron-transfer chain in rat liver mitochondria

In rat liver mitochondria, the macrocyclic polyether, dibenzo-18-crown-6 (polyether XXVIII) inhibits the oxidation of NAD-dependent substrates, as stimulated by ADP, uncouplers and valinomycin plus K⁺. It does not inhibit the oxidation of succinate. It is concluded that polyether XXVIII inhibits electron transfer in the NADH-CoQ span of the respiratory chain. This is a process that is reversed by menadione. Inhibition of oxidation of NAD-dependent substrates in K⁺-depleted mitochondria induced by the polyether is reversed by concentrations of K⁺ higher than 60 mM, and also by Li⁺, a cation that does not complex with polyether XXVIII. As assayed by swelling mitochondria, reversal of the inhibition of electron transfer is accompanied by influx of monovalent cations. Polyether XXVIII also inhibits in submitochondrial particles the aerobic oxidation of NADH, but not that of succinate; this inhibition is also reversed by K⁺ at high concentrations, and Li⁺. The data are consistent with the hypothesis that a monovalent cation is required for maximal rates of electron transport in the NADH-CoQ span of the respiratory chain.     

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.     

Oxidation processes and ubiquinone localization in the branched respiratory system of mi-1 mutant of Neurospora crassa.

1. Stimulation of succinate oxidation in mi-1 mitochondria by Mg2+ and Pi is abolished on uncoupling, which points to the energy-linked activation of succinate oxidation. 2. Mitochondria exhibited respiratory control with succinate and NADH when the cyanide-insensitive oxidation was inhibited by salicylhydroxamic acid (SHAM). SHAM lowered the oxidation rate with NADH and succinate to the same level, though the NADH oxidation rate was 2.5 times as high as with succinate. 3. Despite the high stimulation of succinate oxidation via the SHAM-sensitive pathway in the active and controlled state of mitochondria, the redox state of UQ in all metabolic states remains unchanged. On inhibition of the cyanide-insensitive pathway, UQ reduction is greatly increased only in the controlled and active state. With NADH as a substrate, UQ does not respond to the metabolic states of mitochondria. 4. The redox changes of cytochrome c parallel those of UQ. 5. Branching of the respiratory chain in mi-1 mitochondria is discussed.     

Some Reactions of Isolated Corn Mitochondria Influenced by Juglone

The effects of juglone on the uptake of O₂ by excised corn roots (Zea mays L., Wf9 cms- T × M14) and isolated corn mitochondria arc reported. The O₂ uptake by excised corn roots, as measured by an O₂ electrode, was inhibited more than 90% after a one-hour treatment of 500 μM juglone. Lesser inhibitions were observed with 50 μM and 250 μM juglone. In a KC1 reaction medium in the absence of inorganic phosphate (Pi), juglone stimulated the rate of O₂ uptake by isolated mitochondria oxidizing NADH, succinate, or malate + pyruvate. In the presence of Pi, juglone concentrations of 3 μM and greater inhibited the state 3 oxidation rates of succinate and malate + pyruvate, lowered respiratory control and ADP/O ratios obtained from the oxidation of NADH, malate + pyruvate, or succinate, and reduced the coupled deposition of calcium phosphate within isolated mitochondria driven, by the oxidation of malate + pyruvate. The inhibition of state 3 O₂ uptake by isolated mitochondria, an oxidative state in which electron transfer is coupled to ATP production, is seen to correlate with the inhibition affected by juglone when applied to tissues in vivo.     

Cooperative Substrate Oxidation by Mitochondria from Castor Bean Hypocotyls

Cooperative oxidation of succinate and exogenous NADH was followed in the mitochondria from five- to six-day-old castor bean (Ricinus communisL.) seedlings. Although succinate was oxidized at a much higher rate than NADH, the former inconsiderably (less than 15%) inhibited the oxidation of the latter substrate in state 4, while, in state 3 (in the presence of ATP), the two substrates did not compete and were jointly oxidized. When two substrates were oxidized by the mitochondria with the alternative CN-resistant oxidase (AO) inhibited with salicylhydroxamic acid, the rate of NADH oxidation in state 4 dropped by over 40% as compared to the initial rate. Meanwhile, the rate of succinate oxidation was not considerably affected by AO inhibition. We believe that one of the AO functions in the mitochondria is to provide for noncompeting oxidation of two (or more) substrates by employing two (or several) dehydrogenases of the respiratory chain.     

Effects of flavone on the oxidative properties of intact plant mitochondria

The effects of flavone on the oxidative and phosphorylative properties of plant mitochondria from potato tubers and etiolated mung bean hypocotyls were investigated. Flavone inhibited the state 3 oxidation rates of malate, NADH and, to a lesser extent, succinate but was without effect on the ascorbate-TMPD oxidation rate. The inhibition was the same whether the mitochondria were in state 3 or in an uncoupled state 3. When 100 μM flavone was added during the state 4, the tight coupling of succinate or NADH oxidation was not released. In the electron transfer chain, flavone inhibition appeared to be located in the flavoprotein region. All forms of NADH dehydrogenases seemed to be affected but the greatest inhibition appeared when exogenous NADH was used.     

Effects of Q metabolites and related compounds on mitochondrial succinate and NADH oxidase systems

The effects of Q metabolites (Q acid-I, Q acid-II) and related compounds (dihydro Q acid-I, dehydro Q acid-II, QS-n, and their esters) on mitochondrial succinate and NADH oxidase systems were investigated. The activity restoring succinate oxidation in acetone-treated beef heart mitochondria was found to decrease with descending order of carbon number (n) of the side chain of the Q metabolites; activity was restored with Q acid-I (n = 7) to one-third as much as that with Q-7 and Q-10, but Q acid-II (n = 5) did not restore any activity. Of the related compounds with a carboxyalkyl group (QS-n), QS-16-QS-18 (n = 16–18) were found to be most active, and their activities were also correlated with n. The relationship between the restoration of activity and the partition coefficient was considered. NADH oxidation in pentane-treated beef heart submitochondrial particles could be restored with esters of low molecular weight quinones to the same extent as with Q-10, but not with the metabolites.     

Glyceollin: a site-specific inhibitor of electron transport in isolated soybean mitochondria

The glyceollin inhibition of electron transport by isolated soybean and corn mitochondria was similar to that of rotenone, acting at site I between the internal NADH dehydrogenase and coenzyme Q. Coupled state 3 malate oxidation was inhibited by glyceollin and rotenone with apparent K_i values of about 15 and 5 micromolar, respectively. Carbonylcyanide m-chlorophenyl hydrazone uncoupled state 4 malate oxidation was also inhibited by glyceollin and rotenone, but uncoupled succinate and exogenous NADH state 4 oxidation was only slightly inhibited by both compounds. Glyceollin also inhibited ferricyanide reduction with malate as the electron donor, with an apparent K_i of 5.4 micromolar, but failed to inhibit such reduction with succinate or externally added NADH as electron donors. Glyceollin did not inhibit state 4 oxidation of malate, succinate, or exogenous NADH. Glyceollin did not act as a classical uncoupler or as an inhibitor of oxidative phosphorylation.     

The Interaction between Exogenous NADH Oxidase and Succinate Oxidase in Jerusalem Artichoke (Helianthus tuberosus) Mitochondria

Most isolated plant mitochondria oxidize exogenous NADH viaan electron transport pathway which is resistant to piericidinA and coupled to the synthesis of two molecules of ATP. Resultspresented show that succinate can inhibit this oxidation ofadded NADH. The inhibition was most marked in the absence ofADP (state 4), less obvious in the presence of added ADP (state3), and absent in the presence of a weak acid uncoupling agent.The presence of malonate prevented the inhibition. The degreeof inhibition was dependent on the concentration of succinateand appeared to be non-competitive in nature. The inhibitionwas shown not to be the result of the reversed flow of electronsfrom succinate to NAD^$. The presence of external NADH appearednot to alter the rate of oxidation of succinate.     

The effect of 4-hydroxy-2, 3-trans-pent-en-1-al and maleylaldehyde on some mitochondrial functions

Low concentrations of HPE and MLA inhibited state 3 respiration of rat liver mitochondria in the presence of different NAD⁺-dependent substrates. MLA appeared to be more active than HPE. High aldehyde concentrations inhibited the state 3 respiration with succinate. The restraint of succinate oxidation by HPE and MLA and of glutamate plus malate oxidation by MLA correlated with the inhibition of succinate and glutamate dehydrogenase activites, respectively. HPE inhibited glutamate dehydrogenase at concentrations higher than those affecting glutamate oxidation. Malate dehydrogenase activity was slightly sensitive to HPE and MLA. Both aldehydes inhibited NADH oxidation by freeze-thawed mitochondria. These results suggest the existence of a site particularly sensitive to aldehydes in the electron transport chain between the specific NAD⁺-linked dehydrogenases and ubiquinone.     

The mitochondrial respiratory chain of Rhizopus stolonifer (Ehrenb.:Fr.) Vuill

Rhizopus stolonifer (Ehrenb.:Fr.) Vuill mitochondria contain the complete system for oxidative phosphorylation, formed by the classical components of the electron transport chain (complexes I, II, III, and IV) and the F₁F₀-ATP synthase (complex V). Using the native gel electrophoresis, we have shown the existence of supramolecular associations of the respiratory complexes. The composition and stoichiometry of the oxidative phosphorylation complexes were similar to those found in other organisms. Additionally, two alternative routes for the oxidation of cytosolic NADH were identified: the alternative NADH dehydrogenase and the glycerol-3-phosphate shuttles. Residual respiratory activity after inhibition of complex IV by cyanide was inhibited by low concentrations of n-octyl gallate, indicating the presence of an alternative oxidase. The K_0.5 for the respiratory substrates NADH, succinate, and glycerol-3-phosphate in permeabilized cells was higher than in isolated mitochondria, suggesting that interactions of mitochondria with other cellular elements might be important for the function of this organelle.     

Modes of coenzyme Q function in electron transfer

Summary In the mitochondrial respiratory chain, coenzyme Q acts in different ways. A diffusable coenzyme Q pool as a common substrate-like intermediate links the low-potential complexes with complex III. Its diffusion in the lipids is not rate-limiting for electron transfer, but its content is not saturating for maximal rate of NADH oxidation. Protein-bound coenzyme Q is involved in energy conservation, and may be part of enzyme supercomplexes, as in succinate cytochromec reductase. The reason for lack of kinetic saturation of the respiratory chain by quinone concentration is in the low extent of solubility of monomeric coenzyme Q in the membrane lipids. Assays of respiratory enzymes are performed using water soluble coenzyme Q homologs and analogs; several problems exist in using oxidized quinones as acceptors of coenzyme Q reductases. In particular, for complex I no acceptor appears to favorably substitute the endogenous quinone. In addition, quinone reduction sites in complex III compete with the sites in the dehydrogenases, particularly when using duroquinone. The different extent by which these sites operate when different donor substrates (NADH, succinate, glycerol-3-phosphate) are used is best explained by different exposure of the quinone acceptor sites in the dehydrogenases.     

Two separate pathways underlie NADH and succinate oxidation in swine heart mitochondria: Kinetic evidence on the mobile electron carriers

We have investigated NADH and succinate aerobic oxidation in frozen and thawed swine heart mitochondria. Simultaneous oxidation of NADH and succinate showed complete additivity under a variety of experimental conditions, suggesting that the electron fluxes originating from NADH and succinate are completely independent and do not mix at the level of the so-called mobile diffusible components. We ascribe the results to mixing of the fluxes at the level of cytochrome c in bovine mitochondria: the Complex IV flux control coefficient in NADH oxidation was high in swine mitochondria but very low in bovine mitochondria, suggesting a stronger interaction of cytochrome c with the supercomplex in the former. This was not the case in succinate oxidation, in which Complex IV exerted little control also in swine mitochondria. We interpret the data in swine mitochondria as restriction of the NADH flux by channelling within the I-III₂-IV supercomplex, whereas the flux from succinate shows pool mixing for both Coenzyme Q and probably cytochrome c. The difference between the two types of mitochondria may be ascribed to different lipid composition affecting the cytochrome c binding properties, as suggested by breaks in Arrhenius plots of Complex IV activity occurring at higher temperatures in bovine mitochondria.     

Glucagon treatment of rats activates the respiratory chain of liver mitochondria at more than one site

The rate of reduction of ferricyanide in the presence and absence of antimycin and ubiquinone-1 was measured using liver mitochondria from control and glucagon treated rats. Glucagon treatment was shown to increase electron flow from both NADH and succinate to ubiquinone, and from ubiquinone to cytochrome c. 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) was shown to inhibit the oxidation of glutamate + malate to a much greater extent than that of succinate or duroquinol. Spectral and kinetic studies confirmed that electron flow between NADH and ubiquinone was the primary site of action but that the interaction of the ubiquinone pool with complex 3 was also affected. The effects of various respiratory chain inhibitors on the rate of uncoupled oxidation of succinate and glutamate + malate by control and glucagon treated mitochondria were studied. The stimulation of respiration seen in the mitochondria from glucagon treated rats was maintained or increased as respiration was progressively inhibited with DCMU, 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB), 2-heptyl-4-hydroxyquinoline-n-oxide (HQNO) and colletotrichin, but greatly reduced when inhibition was produced with malonate or antimycin. These data were also shown to support the conclusion that glucagon treatment may cause some stimulation of electron flow through NADH dehydrogenase, succinate dehydrogenase and through the bc1 complex, probably at the point of interaction of the complexes with the ubiquinone pool. The effects of glucagon treatment on duroquinol oxidation and the inhibitor titrations could not be mimicked by increasing the matrix volume, nor totally reversed by aging of mitochondria. These are both processes that have been suggested as the means by which glucagon exerts its effects on the respiratory chain (Armston, A.E., Halestrap, A.P. and Scott, R.D., 1982, Biochim. Biophys. Acta 681, 429-439). It is concluded that an additional mechanism for regulating electron flow must exist and a change in lipid peroxidation of the inner mitochondrial membrane is suggested.     

Inhibition of anion transport across the mitochondrial membrane by amytal

It has been found that amytal competitively inhibits succinate (+ rotenone) oxidation by intact uncoupled mitochondria. Similar results were obtained in metabolic state 3, the K_i value being 0.45 mM. Amytal did not effect succinate oxidation by broken mitochondria and submitochondrial particles (at a concentration which inhibited succinate oxidation by intact mitochondria). Amytal inhibited the swelling of mitochondria suspended in ammonium succinate or ammonium malate but was without effect on the swelling of mitochondria in ammonium phosphate and potassium phosphate in the presence of valinomycin+carbonylcyanide p-trifluoromethoxyphenylhydrazone.Using [¹⁴C] succinate and [¹⁴C] citrate it has been shown that amytal inhibited the succinate/succinate, succinate/P_i, succinate/malate, and citrate/citrate and citrate/malate exchanges. Amytal inhibited P_i transport across mitochondrial membrane only if preincubated with mitochondria. Other barbiturates: phenobarbital, dial, veronal were found to inhibit [¹⁴C]succinate/anion (P_i, succinate, malonate, malate) exchange reactions in a manner similar to amytal. It is concluded that barbiturates non-specifically inhibit the dicarboxylate carrier system, tricarboxylate carrier and P_i translocator. It is postulated that the inhibition of succinate oxidation by barbiturates is caused mainly by the inhibition of succinate and P_i translocation across the mitochondrial membrane.