The Respiratory Chain of Plant Mitochondria: VII. Kinetics of Flavoprotein Oxidation in Skunk Cabbage Mitochondria

The oxidation kinetics of the two high potential flavo-proteins, one (Fp_hf) fluorescent and the other (Fp_ha) nonfluorescent, in mitochondria from skunk cabbage (Symplocarpus foetidus) spadices have been measured by combined spectrophotometry and fluorimetry. In the absence of respiratory inhibitors, both flavoproteins are oxidized at nearly the same rate with half-times between 120 and 160 milliseconds at 24 C. When slight differences in rate are observed, it is Fp_ha which consistently has the shorter half-time. The presence of 0.3 millimolar KCN has no perceptible effect on the oxidation rate of either component. Antimycin A (2 nanomoles per milligram of protein) increases the oxidation half-time of Fp_ha about 3-fold, but it has no effect on the oxidation half-time of Fp_hf. In contrast to these two inhibitors, m-chlorobenzhydroxamic acid—an inhibitor specific to the cyanide insensitive, alternate oxidase pathway in these mitochondria—increases the oxidation half-time of Fp_hf 10-fold to about 2 seconds, while increasing that of Fp_ha only some 20%. This result implies that the flavoprotein Fp_hf mediates electron transport to the alternate oxidase from the region of the mitochondrial respiratory chain encompassing Fp_ha, ubiquinone, and the cytochromes b. The oxidation rate of cytochrome b₅₅₇ is unaffected by either m-chlorobenzhydroxamic acid or cyanide but is strongly inhibited by antimycin A. This result implies that cytochrome b₅₅₇ plays no direct role in the respiratory pathway to the alternate oxidase and is different from cytochrome b₇ found in mitochondria from the spadices of Arum maculatum.     

The Respiratory Chain of Plant Mitochondria: VIII. Reduction Kinetics of the Respiratory Chain Carriers of Mung Bean Mitochondria with Reduced Nicotinamide Adenine Dinucleotide

Addition of 90 micromolar reduced nicotinamide adenine dinucleotide (NADH) in the presence of cyanide to a suspension of aerobic mung bean (Phaseolus aureus) mitochondria depleted with ADP and uncoupler gives a cycle of reduction of electron transport carriers followed by reoxidation, as NADH is oxidized to NAD⁺ through the cyanide-insensitive, alternate oxidase by excess oxygen in the reaction medium. Under these conditions, cytochrome b₅₅₃ and the nonfluorescent, high potential flavoprotein Fp_ha of the plant respiratory chain become completely reduced with half-times of 2.5 to 2.8 seconds for both components. Reoxidation of flavoprotein Fp_ha on exhaustion of NADH is more rapid than that of cytochrome b₅₅₃. There is a lag of 1.5 seconds after NADH addition before any reduction of ubiquinone can be observed, whereas there is no lag perceptible in the reduction of flavoprotein Fp_ha and cytochrome b₅₅₃. The half-time for ubiquinone reduction is 4.5 seconds, and the extent of reduction is 90% or greater. About 30% of cytochrome b₅₅₇ is reduced under these conditions with a half-time of 10 seconds; both cytochrome b₅₆₂ and the fluorescent, high potential flavoprotein Fp_hf show little, if any, reduction. The two cytochromes c in these mitochondria, c₅₄₇ and c₅₄₉, are reduced in synchrony with a half-time of 0.8 second. These two components are already 60% reduced in the presence of cyanide but absence of substrate, and they become completely reduced on addition of NADH. These results indicated that reducing equivalents enter the respiratory chain from exogenous NADH at flavoprotein Fp_ha and are rapidly transported through cytochrome b₅₅₃ to the cytochromes c; once the latter are completely reduced, reduction of ubiquinone begins. Ubiquinone appears to act as a storage pool for reducing equivalents entering the respiratory chain on the substrate side of coupling site 2. It is suggested that flavoprotein Fp_ha and cytochrome b₅₅₃ together may act as the branching point in the plant respiratory chain from which forward electron transport can take place to oxygen through the cytochrome chain via cytochrome oxidase, or to oxygen through the alternate, cyanide-insensitive oxidase via the fluorescent, high potential flavoprotein Fp_hf.     

The Respiratory Chain of Plant Mitochondria: XIV. Ordering of Ubiquinone, Flavoproteins, and Cytochromes in the Respiratory Chain

The effect of initial oxygen concentration on the rate and extent of oxidation of the respiratory chain carriers of anaerobic mitochondria from mung bean (Phaseolus aureus) seedlings was examined. The substrate was succinate, with malonate added to give malonate to succinate ratios of 6 to 12, thereby minimizing the flow of reducing equivalents from substrate and insuring maximal extent of oxidation of the carriers. The ratio of oxidizing equivalents available from oxygen to reducing equivalents available from reduced ubiquinone, designated the equivalents ratio, varied from 30 to 1. Cytochromes aa₃ and c₅₄₇ have unaltered oxidation half-times, designated t_{½ on}, as the equivalents ratio is reduced from 30 to 3, and the extent of oxidation is decreased by about 25%. The time of the oxidation-reduction cycle induced by the oxygen pulse, calculated from the point of half oxidation to that of half reduction and designated t_{½ off}, decreases 200 fold with this reduction in equivalents ratio. The oxidation half-time, t_{½ on}, for ubiquinone is unaltered by decreasing the equivalents ratio from 6 to 1; the value of t_{½ off} decreases only 30% while the extent of oxidation decreases 50%. The values of t_{½ on} and t_{½ off} and the extent of oxidation of cytochrome b₅₅₃ and flavoprotein Fp_ha were all much reduced at low equivalents ratios. The results, plus results from previous studies, indicate that there is the following linear sequence of components in the plant respiratory chain:     

The Respiratory Chain of Plant Mitochondria. II. Oxidative Phosphorylation in Skunk Cabbage Mitochondria

Mitochondria were prepared from the spadices of skunk cabbage (Symplocarpus foetidus) whose respiratory rate with succinate and malate showed 15% to 30% sensitivity to cyanide inhibition, and which showed respiratory control by added ADP. The observed respiratory control ratios ranged from 1.1 to 1.4. The change in pH of the mitochondrial suspension was recorded simultaneously with oxygen uptake: alkalinization of the medium, expected for phosphorylation of ADP, coincided with the period of acceleration in oxygen uptake caused by addition of an ADP aliquot. The ADP/O ratios obtained were 1.3 for succinate and 1.9 for malate. In the presence of 0.3 mm cyanide, the ADP/O ratio for succinate was zero, while that for malate was 0.7. These results are consistent with the existence of an alternate oxidase which interacts with the flavoprotein and pyridine nucleotide components of the respiratory chain and which, in the presence of cyanide, allows the first phosphorylation site to function with an efficiency of about 70%. In the absence of respiratory inhibitors, the efficiency of each phosphorylation site is also about 70%. This result implies that diversion of reducing equivalents through the alternate oxidase, thereby bypassing the 2 phosphorylation sites associated with the cytochrome components of these mitochondria, occurs to a negligible extent during the oxidative phosphorylation of ADP or State 3.Addition of ADP or uncoupler to skunk cabbage mitochondria respiring in the controlled state or State 4, results in reduction of cytochrome c and the oxidation of the cytochromes b, ubiquinone and pyridine nucleotide. A site of interaction of ADP with the respiratory chain between cytochromes b and cytochrome c is thereby identified by means of the crossover theorem. Flavoprotein measured by fluorescence is also oxidized upon addition of ADP or uncoupler, but flavoprotein measured by optical absorbance changes becomes more reduced under these conditions. Depletion of the mitochondria by pretreatment with ADP and uncoupler prevents reduction of most of the fluorescent flavoprotein by succinate. These results indicate that skunk cabbage mitochondria contain both high and low potential flavo-proteins characterized by different fluorescence/absorbance ratios similar to those demonstrated to be part of the respiratory chain in mitochondria from animal tissues.     

Contribution of different enzymes to flavoprotein fluorescence of isolated rat liver mitochondria

The fluorescence signal of flavoproteins of rat liver mitochondria was investigated to determine the respective contributions of the various flavoenzymes. About 50% of the overall signal were found to be NAD-linked and caused by alpha-lipoamide dehydrogenase flavin (Em7.4 = -283 mV). Roughly 25% were due to a flavoprotein reducible in a non-NAD-linked reaction. This fluorescent flavoenzyme (Em7.4 = -52 mV) has been tentatively identified as a flavoprotein of the fatty-acid-oxidizing system, most probably the electron transfer flavoprotein. The remaining 25% of the signal are accounted for by flavoenzymes which are reducible by dithionite only. These flavoenzymes were not involved in the flavoprotein fluorescence alterations accompanying changes in electron flow through the respiratory chain. Contributions of other mitochondrial flavoproteins such as succinate dehydrogenase, NADH dehydrogenase, alpha-glycerophosphate dehydrogenase, proline dehydrogenase, and choline oxidase, to the overall flavin fluorescence signal of isolated rat liver mitochondria can be neglected.     

The Respiratory Chain of Plant Mitochondria: XVII. Flavoprotein-Cytochrome b(562) Interaction in Antimycin-treated Skunk Cabbage Mitochondria

During the transition from the aerobic steady state with succinate as substrate to anaerobiosis, in suspensions of skunk cabbage (Symplocarpus foetidus) mitochondria treated with antimycin A, cytochrome b(562) becomes reoxidized to the extent of about 20%, synchronously with the reduction of cytochrome c(549). This reoxidation occurs in both the absence and presence of m-chlorobenzhydroxamic acid, a specific inhibitor for the alternate terminal oxidase of plant mitochondria. A flavoprotein component, amounting to 13% to 15% of the total nonfluorescent mitochondrial flavoprotein, undergoes reduction synchronously with the oxidation of cytochrome b(562) during the aerobic to anaerobic transition with succinate as substrate in the presence of both antimycin A and m-chlorobenzhydroxamic acid. This flavoprotein component remains reduced in the presence of cyanide. The half-time for reduction of the flavoprotein component and cytochrome c(549) and for oxidation of cytochrome b(562) during the aerobic to anaerobic transition with succinate as substrate in the presence of both antimycin A and m-chlorobenzhydroxamic acid is 2 seconds. The half-times for oxidation of cytochrome c(549) and the flavoprotein component are 2.1 and 170 milliseconds, respectively, during the anaerobic to aerobic transition induced by addition of 14 mum O(2) to the mitochondrial suspensions. The half-time for reduction of cytochrome b(562) under these conditions is 150 milliseconds, synchronous with the flavoprotein component. The synchrony of the flavoprotein oxidation and of the cytochrome b(562) reduction at a rate much slower than that of cytochrome c(549) oxidation implies that, in antimycin-treated plant mitochondria, the state of the cytochrome b(562)/antimycin complex is regulated by the redox state of this flavoprotein component, rather than by cytochrome c(549). It is tentatively suggested that these two components are not part of the main sequence of the respiratory chain, but may be part of a multienzyme complex active in the hydroxylation reactions required for ubiquinone biosynthesis in the inner mitochondrial membrane.     

Oxidation-reduction midpoint potentials of mitochondrial flavoproteins and their intramitochondrial localization

Spectrophotometric and fluorimetric substrate couple titrations and potentiometric spectrophotometric titrations were used to determine the oxidation-reduction potentials of components showing absorbance or fluorescence at the wavelengths attributable to the flavoproteins of mitochondria fractionated using digitonin together with sonication. A pure mitoplast fraction devoid of cytochrome b₅ contamination could be obtained using 230 µg digitonin/mg of mitochondrial protein. The digitonin-soluble fraction contained a species havingE _m 7 .4=–123 mV and probably represents the outer membrane flavoproteins. The inner membrane-matrix fraction, treated with ultrasound, provided evidence of a flavoprotein species with low redox potential (E _m 7 .4=–302 mV) in the matrix fraction. The –302 mV component is probably lipoamide dehydrogenase. A high redox potential species withE _m 7 .4=+19 mV in titrations with the succinate fumarate couple was located in the inner membrane vesicles and is probably identical with succinate dehydrogenase. The electron-transferring flavoprotein (ETF) was isolated from bovine heart mitochondria and itsE _m 7 .4=–74 mV determined. The component in the matrix fraction with an apparentE _m 7 .4=–56 mV probably represents ETF, and that in the inner membrane fraction with an apparentE _m 7 .4=–43 mV the NADH dehydrogenase flavoprotein. A component in an apparently low concentration withE _m 7 .4=+30 mV was detected in the inner membrane fraction. This probably represents the ETF-dehydrogenase flavoprotein. The origin of the flavoprotein fluorescence of mitochondria and intact tissues is discussed.     

The Respiratory Chain of Plant Mitochondria: XVI. Interaction of Cytochrome b(562) with the Respiratory Chain of Coupled and Uncoupled Mung Bean Mitochondria: Evidence for Its Exclusion from the Main Sequence of the Chain

Cytochromes b₅₅₃, b₅₅₇, and b₅₆₂ of mung bean (Phaseolus aureus) mitochondria become partially reduced with endogenous substrate on addition of antimycin A to the aerobic mitochondrial suspension. Addition of ATP causes partial reoxidation of the three cytochromes. This partial oxidation by ATP is inhibited by oligomycin and reversed by uncoupler. Ubiquinone does not appear to act as electron acceptor for the oxidation reaction, but a nonfluorescent flavoprotein, or possibly ironsulfur protein, component does appear to act as acceptor. This is consistent with reverse electron transport driven by ATP across the first site of energy conservation of the respiratory chain. Endogenous pyridine nucleotide and the fluorescent flavoprotein with E_m7.2 = −155mv (midpoint potential at pH 7.2, referred to normal hydrogen electrode) in uncoupled mitochondria become reduced in anaerobiosis attained by oxidation of succinate in the absence of respiratory inhibitors of the cytochrome chain, provided that Pi and ATP are present. Under these same conditions, cytochrome b₅₅₇ is completely reduced but cytochrome b₅₆₂ remains nearly completely oxidized. There is no equilibration across the first site of energy conservation between the carriers on the low potential side and cytochrome b₅₆₂ with E_m7.2 = −77mv on the high potential side. It is concluded that cytochrome b₅₆₂ is not a part of the main sequence of electron transport carriers of the mitochondrial respiratory chain of plants; it can participate in redox reactions with the respiratory chain in coupled mitochondria but not in uncoupled mitochondria unless antimycin A is present.     

Functional Imaging of Mitochondria in Saponin-permeabilized Mice Muscle Fibers

Confocal laser-scanning and digital fluorescence imaging microscopy were used to quantify the mitochondrial autofluorescence changes of NAD(P)H and flavoproteins in unfixed saponin-permeabilized myofibers from mice quadriceps muscle tissue. Addition of mitochondrial substrates, ADP, or cyanide led to redox state changes of the mitochondrial NAD system. These changes were detected by ratio imaging of the autofluorescence intensities of fluorescent flavoproteins and NAD(P)H, showing inverse fluorescence behavior. The flavoprotein signal was colocalized with the potentiometric mitochondria-specific dye dimethylaminostyryl pyridyl methyl iodide (DASPMI), or with MitoTracker™ Green FM, a constitutive marker for mitochondria. Within individual myofibers we detected topological mitochondrial subsets with distinct flavoprotein autofluorescence levels, equally responding to induced rate changes of the oxidative phosphorylation. The flavoprotein autofluorescence levels of these subsets differed by a factor of four. This heterogeneity was substantiated by flow-cytometric analysis of flavoprotein and DASPMI fluorescence changes of individual mitochondria isolated from mice skeletal muscle. Our data provide direct evidence that mitochondria in single myofibers are distinct subsets at the level of an intrinsic fluorescent marker of the mitochondrial NAD–redox system. Under the present experimental conditions these subsets show similar functional responses.     

Respiratory Chain of Plant Mitochondria: XVIII. Point of Interaction of the Alternate Oxidase with the Respiratory Chain

Oxidation of the respiratory chain carriers of anaerobic, CO-saturated skunk cabbage (Symplocarpus foetidus) mitochondria, by means of an O₂ pulse, proceeds primarily through the cyanide-insensitive alternate oxidase, since the oxidation of cytochromes a and a₃ takes place with a half-time of 3 seconds, corresponding to the rate of dissociation of CO from reduced cytochrome a₃. Ubiquinone and part of the flavoprotein are oxidized within 1 second under these conditions, and this rapid rate of oxidation is strongly inhibited by m-chlorobenzhydroxamic acid (mCLAM), a specific inhibitor of the alternate oxidase of plant mitochondria. The rate of ubiquinone oxidation under these conditions in white potato (Solanum tuberosum) mitochondria, which have no alternate oxidase, is the same as that in skunk cabbage mitochondria treated with mCLAM. Ubiquinone, thus identified as the carrier common to both the cytochrome and alternate oxidase pathways, is linked to the alternate oxidase by a flavoprotein of midpoint potential 50 millivolts more negative with which it is in equilibrium. This arrangement provides a switch for diverting electron transport primarily through the cytochrome pathway under state 3 conditions and primarily through the alternate oxidase pathway under state 4 conditions.     

The Respiratory Chain of Plant Mitochondria. I. Electron Transport Between Succinate and Oxygen in Skunk Cabbage Mitochondria

The kinetics of oxidation of ubiquinone, flavoprotein, cytochrome c, and the cytochrome b complex in skunk cabbage (Symplocarpus foetidus) mitochondria made anaerobic with succinate have been measured spectrophotometrically and fluorimetrically in the absence of respiratory inhibitor and in the presence of cyanide or antimycin A. No component identifiable by these means was oxidized rapidly enough in the presence of one or the other inhibitor to qualify for the role of alternate oxidase. Cycles of oxidation and rereduction of flavoprotein and ubiquinone obtained by injecting 12 mum oxygen into the anaerobic mitochondrial suspension were kinetically indistinguishable in the presence of cyanide or antimycin A, implying that these 2 components are part of a respiratory pathway between succinate and oxygen which does not involve the cytochromes and does involve a cyanide-insensitive alternate oxidase. The cytochrome b complex shows biphasic oxidation kinetics with half times of 0.018 sec and 0.4 sec in the absence of inhibitor, which increase to 0.2 sec and 1 sec in the presence of cyanide. In the presence of antimycin A, the oxidation of the cytochrome b complex shows an induction period of 1 sec and a half-time of 3.5 sec. A split respiratory chain with 2 terminal oxidases and a branch point between the cytochromes and flavoprotein and ubiquinone is proposed for these mitochondria.     

The Respiratory Chain of Plant Mitochondria: XI. Electron Transport from Succinate to Endogenous Pyridine Nucleotide in Mung Bean Mitochondria

Energy-linked reverse electron transport from succinate to endogenous NAD in tightly coupled mung bean (Phaseolus aureus) mitochondria may be driven by ATP if the two terminal oxidases of these mitochondria are inhibited, or may be driven by the free energy of succinate oxidation. This reaction is specific to the first site of energy conservation of the respiratory chain; it does not occur in the presence of uncoupler. If mung bean mitochondria become anaerobic during oxidation of succinate, their endogenous NAD becomes reduced in the presence of uncoupler, provided that both inorganic phosphate (P_i) and ATP are present. No reduction occurs in the absence of P_i, even in the presence of ATP added to provide a high phosphate potential. If fluorooxaloacetate is present in the uncoupled, aerobic steady state, no reduction of endogenous NAD occurs on anaerobiosis; this compound is an inhibitor of malate dehydrogenase. This result implies that endogenous NAD is reduced by malate formed from the fumarate generated during succinate oxidation. The source of free energy is most probably the endogenous energy stores in the form of acetyl CoA, or intermediates convertible to acetyl CoA, which removes the oxaloacetate formed from malate, thus driving the reaction towards reduction of NAD.     

Electron transport in mitochondria isolated from the flagellate Polytomella caeca

1. Mitochondria isolated from Polytomella caeca contain cytochromes b, c+c₁ and a+a₃ and several flavoprotein species. 2. Electron transport is inhibited by antimycin A, rotenone, piericidin A and cyanide. 3. Spectral data indicate that antimycin A inhibits the reoxidation of reduced cytochrome b. 4. Various types of flavoprotein are characterized by simultaneous spectrophotometric and fluorimetric measurements on antimycin A-inhibited preparations and also by their absorption and fluorescence-emission spectra. 5. The rotenone-sensitive site lies between the two flavoproteins of the respiratory chain, designated FpD1 and FpD2. 6. Other flavoprotein species detected include those involved in the oxidation of succinate and externally added NADH; a large proportion of mitochondrial flavine is reduced by dithionite but not by known respiratory substrates. 7. The kinetics of flavoprotein and cytochrome reactions were studied.     

The Respiratory Chain of Plant Mitochondria: IV. Oxidation Rates of the Respiratory Carriers of Mung Bean Mitochondria in the Presence of Cyanide

The half-time for oxidation of cytochrome b(557) in mitochondria from etiolated mung bean (Phaseolus aureus) hypocotyls is 5.8 milliseconds at 24 Celsius in the absence or presence of 0.3 mm KCN, when the oxidation is carried out by injecting a small amount of oxygenated medium into a suspension of mitochondria made anaerobic in the presence of succinate plus malonate. Since oxygen is consumed by the alternate, cyanide-insensitive respiratory pathway of these mitochondria, cycles of oxidation and reduction can be obtained with the oxygen pulses when cyanide is present. Reduced cytochromes (a + a(3)) also become oxidized at nearly the uninhibited rate under these conditions, a(3) completely and a partially. The half-time for oxidation of c(547) is also unaffected by 0.3 mm KCN, but c(549) has a half-time equal to that of c(547) in the presence of KCN, compared to the shorter one observed in the absence of inhibitor. The maximum extent of oxidation of the cytochromes c is about 70% in the presence of 0.3 mm KCN; this oxidation is rapidly followed by an extensive reduction which is synchronous with the reduction of cytochrome a observed under the same conditions. In the presence of cyanide, it appears likely that the cytochromes c and b(557) are oxidized by cytochrome oxidase in oxygen pulse experiments, rather than by the alternate oxidase. The oxidation of cytochrome b(553) is partially inhibited by KCN, but complete oxidation is attained in the aerobic steady state with excess oxygen. If the oxygen pulse experiment is carried out in the presence of sufficient malonate so that entry of reducing equivalents into the respiratory chain occurs at a rate negligible compared to inter-carrier electron transport, the half-time for flavoprotein oxidation is unaffected by 0.3 mm KCN while that for ubiquinone oxidation is but 2-fold larger. The observed net oxidation rate of these two carriers in mung bean mitochondria is more sensitive to the entry rate of reducing equivalents, as set by succinate concentration and malonate to succinate ratio, then it is in skunk cabbage (Symplocarpus foetidus) mitochondria. These observations are interpreted in terms of a respiratory carrier Y, placed between flavoprotein plus ubiquinone and the cytochromes, which is the fork in the split respiratory pathway to the two terminal oxidases and which has lower electron transport capacity in mung bean mitochondria than in skunk cabbage mitochondria.     

Spectral properties of fluorescent flavoproteins of isolated rat liver mitochondria

The different flavoproteins contributing to flavin fluorescence of isolated rat liver mitochondria have distinct excitation and emission spectra. The NAD-linked flavin component was identified as alpha-lipoamide dehydrogenase, while the non-NAD-linked component was found to be electron transfer flavoprotein. The differences in excitation and emission properties of the mitochondrial flavoproteins permit selective recording of their redox state changes in isolated mitochondria.     

Respiratory Chain of Antimycin A-producing Streptomyces antibioticus

An active respiratory chain system was demonstrated in sonically treated mycelium of Streptomyces antibioticus, the producer of antimycin A. The respiratory electron transfer from substrate to oxygen proceeded successively through flavoprotein(s), b-, c-, and a-type cytochromes, and terminated with the cyanide-sensitive cytochrome oxidase. The cytochrome composition of the culture was not affected by the age of the mycelium, the intensity of antimycin A production, or differences in the media. Slater factor, coenzyme Q, and vitamin K were not interposed as hydrogen carriers in the respiratory chain between flavoproteins and cytochromes. The oxidation of reduced nicotinamide adenine dinucleotide and succinate was unaffected by antimycin A. Evidence is presented in support of the absence of the antimycin A-sensitive site from the electron transport system of S. antibioticus.     

The Respiratory Chain of Plant Mitochondria: XII. Some Aspects of the Energy-linked Reverse Electron Transport from the Cytochromes c to the Cytochromes b in Mung Bean Mitochondria

The cytochromes c of mung bean (Phaseolus aureus) mitochondria become reduced when sulfide, a cytochrome oxidase inhibitor free from uncoupling side effects, is added to the aerobic mitochondrial suspension in the absence of added substrate. The cytochromes b remain largely oxidized. Subsequent addition of ATP results in partial oxidation of the cytochromes c and partial reduction of the cytochromes b due to ATP-driven reverse electron transport through the second site of energy conservation, or coupling site, of the respiratory chain. Cytochrome a is also oxidized under these conditions, but there is no concomitant reduction of the flavoprotein components, of ubiquinone, or of endogenous pyridine nucleotide. The reaction is abolished by oligomycin. The reducing equivalents transported from the cytochromes c and a in ATP-driven reverse electron transport are about 2-fold greater than those which appear in the cytochromes b. It is suggested that the equivalents not accounted for are present in a coupling site enzyme at the second site of energy conservation which interacts with the respiratory chain carriers by means of the dithiol-disulfide couple; this couple would not show absorbance changes with redox state over the wavelength range examined. With succinate present, reverse electron transport can be demonstrated at both coupling sites in both the aerobic steady state and in anaerobiosis. ATP-driven reverse electron transport in anaerobiosis maintains cytochrome a 30% oxidized while endogenous pyridine nucleotide is 50% reduced.     

Fluorescence spectroscopic detection of mitochondrial flavoprotein redox oscillations and transient reduction of the NADPH oxidase-associated flavoprotein in leukocytes

Steady-state and time-resolved fluorescence spectroscopy and fluorescence microscopy of leukocyte flavoproteins have been performed. Both living human peripheral blood monocytes and neutrophils have been utilized as experimental models, as the former relies much more heavily on mitochondrial metabolism for energy production than the latter. We confirm previous studies indicating that cellular flavoproteins absorb at 460 nm and emit at 530 nm, very similar to that of the FAD moiety. Furthermore, the emission properties of intracellular flavoproteins were altered by the metabolic inhibitors rotenone, antimycin A, azide, cyanide, DNP (2,4-dinitrophenol), and FCCP [carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone]. Kinetic studies revealed flavoprotein emission oscillations in both monocytes and neutrophils. The flavoprotein intensity oscillations correlated with the physiological status of the cell and the nature of membrane receptor ligation. Microscopy revealed the presence of flavoprotein fluorescence in association with the plasma membrane, intracellular granules and distributed throughout the cytoplasm, presumably within mitochondria. Metabolic inhibitors such as cyanide suggest that the plasma membrane and granular components are cyanide-insensitive and therefore are likely associated with the flavoprotein component of the NADPH oxidase, which is located in these two compartments. This interpretation was found to be consistent with structural localization of the NADPH oxidase using an antibody molecule specific for this protein. Using peripheral blood neutrophils, which display less active mitochondria, and time-resolved emission spectroscopy, we show that the NADPH oxidase-associated flavoprotein undergoes a periodic transient reduction of about 54±2 ms in living cells. This finding is consistent with prior studies indicating that propagating substrate (NADPH) waves periodically promote electron transport across the NADPH oxidase.