Oxidation of Reduced Nicotinamide Adenine Dinucleotide Phosphate by Potato Mitochondria: INHIBITION BY SULFHYDRYL REAGENTS

Potato tuber mitochondria oxidized exogenous NADH and exogenous NADPH at similar rates; the electron transfer inhibitor rotenone did not inhibit the oxidation of either substrate. Submitochondrial particles, prepared from potato tuber mitochondria, exhibited a greater capacity to oxidize NADH than NADPH; rotenone inhibited the oxidation of NADH by 29% and the oxidation of NADPH by 16%. The oxidation of both NADH and NADPH by potato mitochondria exhibited pH optima of 6.8, and although substantial NADH oxidase activity was observed at pH 8.0, little NADPH oxidase activity was detected at that pH. The oxidation of NADPH by the mitochondria was more sensitive to inhibition by EDTA than was the oxidation of NADH.     

Properties of substantially chlorophyll-free pea leaf mitochondria prepared by sucrose density gradient separation

Mitochondria isolated from pea leaves (Pisum sativum L. var Massey Gem) and purified on a linear sucrose density gradient were substantially free of contamination by Chl and peroxisomes. They showed high respiratory rates and good respiratory control and ADP/O ratios. Malate, glutamate, succinate, glycine, pyruvate, α-ketoglutarate, NADH, and NADPH were oxidized but little or no oxidation of citrate, isocitrate, or proline was detected. The oxidation of NADPH by the purified mitochondria did not occur via a transhydrogenase or phosphatase converting it to NADH. NADPH oxidation had an absolute requirement for added Ca²⁺, whereas NADH oxidation proceeded in its absence. In addition, oxidation of the two substrates showed different sensitivities to chelators and sulfhydryl reagents, and faster rates of O₂ uptake were observed with both substrates than with either alone. This indicates that the NADPH dehydrogenase is distinct from the exogenous NADH dehydrogenase.     

Isolated durum wheat and potato cell mitochondria oxidize externally added NADH mostly via the malate/oxaloacetate shuttle with a rate that depends on the carrier-mediated transport

We investigated whether and how mitochondria from durum wheat (Triticum durum Desf.) and potato (Solanum tuberosum), isolated from etiolated shoots and a cell suspension culture, respectively, oxidize externally added NADH via the mitochondrial shuttles; in particular, we compared the shuttles and the external NADH dehydrogenase (NADH DHExt) with respect to their capacity to oxidize external NADH. We found that external NADH and NADPH can be oxidized via two separate DHExt, whereas under conditions in which the activities of NAD(P)H DHExt are largely prevented, NADH (but not NADPH) is oxidized in the presence of external malate (MAL) and MAL dehydrogenase, in a manner sensitive to several non-penetrant compounds according to the occurrence of the MAL/oxaloacetate (OAA) shuttle. In durum wheat mitochondria and potato cell mitochondria, the rate of NADH oxidation was limited by the rate of a novel carrier, the MAL/OAA antiporter, which is different from other carriers thought to transport OAA across the mitochondrial membrane. No NAD(P)H oxidation occurred arising from the MAL/Aspartate and the alpha-glycerophosphate/dihydroxyacetonphosphate shuttles. We determined the kinetic parameters of the enzymes and the antiporter involved in NADH oxidation, and, on the basis of a kinetic analysis, we showed that, at low physiological NADH concentrations, oxidation via the MAL/OAA shuttle occurred with a higher efficiency than that due to the NADH DHExt (about 100- and 10-fold at 1 microm NADH in durum wheat mitochondria and in potato cell mitochondria, respectively). The NADH DHExt contribution to NADH oxidation increased with increasing NADH concentration.     

Properties of the oxidation of exogenous NADH and NADPH by plant mitochondria. Evidence against a phosphatase or a nicotinamide nucleotide transhydrogenase being responsible for NADPH oxidation

(1) The optimum pH for the oxidation of exogenous NADH by mitochondria from both Jerusalem artichoke (Helianthus tuberosus) tubers and Arum maculatum spadices was 7.0–7.1. NADPH oxidation had a lower optimum pH of 6.6 in Arum and 6.0 in Jerusalem artichoke mitochondria. In both types of mitochondria the rates of NADH and NADPH oxidation were identical below pH 6.0–5.5. (2) It is shown conclusively that neither a phosphatase converting NADPH to NADH nor a nicotinamide nucleotide transhydrogenase was involved in the oxidation of NADPH by these mitochondria. (3) Palmitoyl-CoA, an inhibitor of transhydrogenase activity in mammalian mitochondria, inhibits both NADH and NADPH oxidation by plant mitochondria with a K_i of about 10 μM. (4) It is concluded that the known properties of NAD(P)H oxidation are best explained by assuming the presence of a second dehydrogenase specific for NADPH. At low pH, electron flow from the two dehydrogenases to oxygen shares a common rate-limiting step.     

Oxidation of External NAD(P)H by Purified Mitochondria from Fresh and Aged Red Beetroots (Beta vulgaris L.)

Mitochondria were isolated from fresh beetroots (Beta vulgaris L. cvs Rubria and Nina) by differential centrifugation followed by Percoll gradient centrifugation. These purified mitochondria oxidized external NADH, although relatively slowly (20-40 versus 100-120 nanomoles oxygen per minute times milligram protein for NADH and succinate oxidation, respectively), with respiratory control ratios of two to three and ADP/O ratios of 1.2 to 1.6. NADPH was also oxidized, but even more slowly and with little or no coupling. The optimum for both NADH and NADPH oxidation by fresh beetroot mitochondria was pH 6. The rate of external NADH oxidation by isolated mitochondria was enhanced threefold during storage of the intact tubers at 10°C for 12 weeks. The optimum of the induced NADH oxidation was approximately pH 6.8. Succinate and malate oxidation only increased by 30% during the same period and NADPH oxidation was constant. This is strong evidence that NADH and NADPH oxidation are catalyzed by different enzymes at least in beetroots. Activity staining of nondenaturing polyacrylamide gels with NADH and Nitro Blue Tetrazolium did not show differences in banding pattern between mitochondria isolated from fresh and stored beetroots. The induction is discussed in relation to physiological aging processes.     

The oxidation of external NADH by an intermembrane electron transfer in mitochondria from the ubiquinone-deficient mutant E3-24 of Saccharomyces cerevisiae

Cells of the E3-24 mutant of the strain D273-10B of Saccharomyces cerevisiae, grown in a fermentable substrate not showing catabolite repression of respiration (2% galactose), are able to respire, in spite of their ubiquinone deficiency in mitochondrial membranes. Mitochondria isolated from these mutant cells oxidize exogenous NADH through a pathway insensitive to antimycin A but inhibited by cyanide. Addition of methanolic solutions of ubiquinone homologs stimulates the oxidation rate and restores antimycin A sensitivity in both isolated mitochondria and whole cells. Mersalyl preincubation of isolated mitochondria inhibits both NADH oxidation and NADH-cytochrome c oxido-reductase activity (assayed in the presence of cyanide) with the same pattern. Electrons resulting from the oxidation of exogenous NADH reduce both cytochrome b5 and endogenous cytochrome c. The increase in ionic strength stimulates NADH oxidation, which is also coupled to the ATP synthesis with an ATP/O ratio similar to that obtained with ascorbate plus N,N,N',N'-tetramethyl-p-phenylendiamine (TMPD) as substrate. The effect of cyanide on these activities and on NADH-induced endogenous cytochrome c reduction is also comparable. These results support the existence in vivo and in isolated mitochondria of a energy-conserving pathway for the oxidation of cytoplasmatic NADH not related to the dehydrogenases of the inner membrane, the ubiquinone, and the b-c1 complex, but involving a cytochrome c shuttle between the NADH-cytochrome c reductase of the outer membrane and cytochrome oxidase in the inner membrane.     

Cyanide-Resistant Respiration in Suspension Cultured Cells of Nicotiana glutinosa L

The respiration of dark-grown Nicotiana glutinosa L. cells in liquid suspension culture was found to be highly cyanide resistant and salicylhydroxamic acid (SHAM) sensitive, indicative of an active alternative respiratory pathway. This was especially true during the lag and logarithmic phases of the 14-day growth cycle. Mitochondria isolated from logarithmically growing cells exhibited active oxidation of malate, succinate, and exogenous NADH. Oxidation of all three substrates had an optimum pH of 6.5 and all were highly resistant to inhibited by cyanide and sensitive to SHAM. Respiratory control was exhibited by all three substrates but only if SHAM was present to block the alternative pathway and divert electrons to the phosphorylating cytochrome pathway. The cyanide-resistant oxidation of exogenous NADH has previously only been associated with Arum spadix mitochondria. Coemergence during evolution of the alternative respiratory pathway and the exogenous NADH dehydrogenase in plant mitochondria as a possible mechanism for removal of cytoplasmic NADH is proposed. Evidence is presented which suggests that mitochondrial assays should be performed at pH 6.5.     

Respiration of Mitochondria Isolated from Leaves and Protoplasts of Avena sativa

Mitochondria isolated from mesophyll protoplasts differed from mitochondria isolated directly from leaves of Avena sativa in that protoplast mitochondria (a) had a lower overall respiratory capacity, (b) were less able to use low concentrations of exogenous NADH, (c) did not respond rapidly or strongly to added NAD, (d) appeared to accumulate more oxaloacetate, and (e) oxidized both succinate and tetramethyl-p-phenylene-diamine (an electron donor for cytochrome oxidase) more slowly than did leaf mitochondria. It is concluded that cytochrome oxidase activity was inhibited, the external NADH dehydrogenase had a reduced affinity for NADH, succinate oxidation was inhibited, NAD and oxaloacetate porters were probably inhibited, and accessibility to respiratory paths may have been reduced in protoplast mitochondria. The results also suggest that there was a reduced affinity of a succinate porter for this substrate in oat mitochondria. In addition, all oat mitochondria required salicylhydroxamic acid (SHAM) as well as cyanide to block malate and succinate oxidation. Malate oxidation that did not appear to saturate the cytochrome pathway was sensitive to SHAM in the absence of cyanide, suggesting that the oat mitochondria studied had concomitant alternative and subsaturating cytochrome oxidase pathway activity.     

Characteristics of External NADH Oxidation by Beetroot Mitochondria

Mitochondria isolated from fresh red beetroot (Beta vulgaris L.) tissue do not oxidize external NADH with O₂ as the electron acceptor. These mitochondria have a rotenone- and antimycin-insensitive pathway of NADH oxidation associated with the outer membrane and are capable of reducing cytochrome c or potassium ferricyanide. They are also capable of oxidizing internal NADH via the inner membrane electron transport chain with normal rotenone and antimycin sensitivity and ADP/O ratios. They differ from other plant mitochondria in the apparent lack of the NADH dehydrogenase located on the outer surface of the inner membrane. It is shown that this activity develops during the aging of red beetroot slices in aerated dilute CaSO₄ solutions, and is present in the mitochondria isolated from aged tissue.     

Nitrite-driven anaerobic ATP synthesis in barley and rice root mitochondria

Mitochondria isolated from the roots of barley (Hordeum vulgare L.) and rice (Oryza sativa L.) seedlings were capable of oxidizing external NADH and NADPH anaerobically in the presence of nitrite. The reaction was linked to ATP synthesis and nitric oxide (NO) was a measurable product. The rates of NADH and NADPH oxidation were in the range of 12–16 nmol min⁻¹ mg⁻¹ protein for both species. The anaerobic ATP synthesis rate was 7–9 nmol min⁻¹ mg⁻¹ protein for barley and 15–17 nmol min⁻¹ mg⁻¹ protein for rice. The rates are of the same order of magnitude as glycolytic ATP production during anoxia and about 3–5% of the aerobic mitochondrial ATP synthesis rate. NADH/NADPH oxidation and ATP synthesis were sensitive to the mitochondrial inhibitors myxothiazol, oligomycin, diphenyleneiodonium and insensitive to rotenone and antimycin A. The uncoupler FCCP completely eliminated ATP production. Succinate was also capable of driving ATP synthesis. We conclude that plant mitochondria, under anaerobic conditions, have a capacity to use nitrite as an electron acceptor to oxidize cytosolic NADH/NADPH and generate ATP.     

Reduction of superoxide production by mitochondria oxidizing NADH in the presence of organic acids

Effects of multiple substrates on oxygen uptake and superoxide production by mitochondria isolated from the pericarp tissue of green bell pepper (Capsicum annuum L.) were studied. Mitochondria isolated from peppers stored at 4 °C for 5 and 6 days had higher rates of oxygen uptake and were less sensitive to cyanide than mitochondria isolated from freshly harvested peppers. Succinate enhanced state 2 and state 4 rates of oxygen uptake with exogenous NADH in the absence of cytochrome path inhibitors, but not state 3 rates by mitochondria isolated from either freshly harvested or cold-stored bell peppers. The sensitivity of NADH oxidation to cyanide was reduced by both malate and succinate in mitochondria from cold-stored bell peppers, whereas only succinate was effective in mitochondria from freshly harvested peppers.Mitochondria isolated from both freshly harvested peppers and those stored at 4 °C for 5 and 6 days produced superoxide in the absence of exogenous substrates. Superoxide production by mitochondria from freshly harvested bell peppers increased when the mitochondria were supplied with malate, succinate or NADH, but only NADH enhanced superoxide production by mitochondria from cold-stored peppers. Both succinate and malate reduced the production of superoxide by mitochondria isolated from cold-stored bell peppers. Succinate and malate as second substrates also reduced the production of superoxide with NADH by mitochondria from both freshly harvested and cold-stored bell peppers. Malonate, a competitive inhibitor of succinate dehydrogenase, was inhibitory to oxygen uptake and to superoxide production.Mitochondria isolated from cold-stored bell peppers converted succinate to pyruvate at 25 °C at considerably higher rates than those of mitochondria from freshly harvested bell peppers. Since pyruvate has been shown to activate the alternative oxidase and the presence of pyruvate is essential for continued alternative oxidase activity, we suggest that pyruvate limits superoxide production by enhancing the flow of electrons through the alternative path. A direct scavenging of superoxide by succinate, malate and pyruvate, however, cannot be ruled out.     

The nuclear origin of the non-phosphorylating NADH dehydrogenases of plant mitochondria.

The oxidation of matrix and cytosolic NADH by isolated beetroot and wheat leaf mitochondria was investigated to determine whether the rotenone-insensitive NADH dehydrogenases of plant mitochondria were the products of nuclear or mitochondrial genes. After aging beetroot tissue (slicing and incubating in a CaSO4 solution), the induction of the level of matrix NADH oxidation in the presence of rotenone was greatly reduced in mitochondria isolated from tissue treated with cycloheximide, a nuclear protein synthesis inhibitor. This was also true for the oxidation of cytosolic NADH. Mitochondria isolated from chloramphenicol-treated tissue exhibited greatly increased levels of both matrix and external rotenone-insensitive NADH oxidation when compared to the increase due to the aging process alone. This increase was not accompanied by an increase in matrix NAD-linked substrate dehydrogenases such as malic enzyme nor intra-mitochondrial NAD levels. Possible explanations for this increase in rotenone-insensitive NADH oxidation are discussed. Based on these results we have concluded that the matrix facing rotenone-insensitive NADH dehydrogenase of plant mitochondria is encoded by a nuclear gene and synthesis of the protein occurs in the cytosol.     

Evidence for the role of malic enzyme in the rapid oxidation of malate by cod heart mitochondria

Mitochondria isolated from the heart of cod (Gadus morrhua callarias) oxidized malate as the only exogenous substrate very rapidly. Pyruvate only slightly increased malate oxidation by these mitochondria. This is in contrast with the mitochondria isolated from rat and rabbit heart which oxidized malate very slowly unless pyruvate was added. Arsenite and hydroxymalonate (an inhibitor of malic enzyme) inhibited the respiration rate of mitochondria isolated from cod heart, when malate was the only exogenous substrate. Inhibition caused by hydroxymalonate was reversed by the addition of pyruvate. In the presence of arsenite, malate was converted to pyruvate by cod heart mitochondria. Cod heart mitochondria incubated in the medium containing Triton X-100 catalyzed the reduction of NADP+ in the presence of L-malate and Mn2+ at relatively high rate (about 160 nmoles NADPH formed/min/mg mitochondrial protein). The oxidative decarboxylation of malate was also taking place when NADP+ was replaced by NAD+ (about 25 nmol NADH formed per min per mg mitochondrial protein). These results suggest that the mitochondria contain both NAD+- and NADP+-linked malic enzymes. These two activities were eluted from DEAE-Sephacel as two independent peaks. It is concluded that malic enzyme activity (presumably both NAD+- and NADP+-linked) is responsible for the rapid oxidation of malate (as the only external substrate) by cod heart mitochondria.     

Transport of reduced nicotinamide–adenine dinucleotide into mitochondria of rat white adipose tissue

Mitochondria from rat white adipose tissue were prepared, exhibiting good respiratory control and P/O ratios. They would not oxidize NADH unless NNN'N'-tetramethyl-p-phenylenediamine was added as a carrier of reducing equivalents. These mitochondria were found to oxidize neither l-glycerol 3-phosphate nor l-glutamate plus l-malate at significant rates. The activity of aspartate aminotransferase in these mitochondria was found to be low compared with that found in rat liver mitochondria. As a consequence of this, the adipose-tissue mitochondria exhibited very low rates of cytoplasmic NADH oxidation in a reconstituted Borst (1962) cycle compared with liver mitochondria.     

Changes in oxidative properties of Kalanchoe blossfeldiana leaf mitochondria during development of Crassulacean acid metabolism

Kalanchoe blossfeldiana plants grown under long days (16 h light) exhibit a C₃-type photosynthetic metabolism. Switching to short days (9 h light) leads to a gradual development of Crassulacean acid metabolism (CAM). Under the latter conditions, dark CO₂ fixation produces large amounts of malate. During the first hours of the day, malate is rapidly decarboxylated into pyruvate through the action of a cytosolic NADP⁺-or a mitochondrial NAD⁺-dependent malic enzyme. Mitochondria were isolated from leaves of plants grown under long days or after treatment by an increasing number of short days. Tricarboxylic acid cycle intermediates as well as exogenous NADH and NADPH were readily oxidized by mitochondria isolated from the two types of plants. Glycine, known to be oxidized by C₃-plant mitochondria, was still oxidized after CAM establishment. The experiments showed a marked parallelism in the increase of CAM level and the increase in substrate-oxidation capacity of the isolated mitochondria, particularly the capacity to oxidize malate in the presence of cyanide. These simultaneous variations in CAM level and in mitochondrial properties indicate that the mitochondrial NAD⁺-malic enzyme could account at least for a part of the oxidation of malate. The studies of whole-leaf respiration establish that mitochondria are implicated in malate degradation in vivo. Moreover, an increase in cyanide resistance of the leaf respiration has been observed during the first daylight hours, when malate was oxidized to pyruvate by cytosolic and mitochondrial malic enzymes.Abbreviations CAM Crassulacean acid metabolism - MDH malate dehydrogenase - ME malic enzyme     

Oxidation of reduced nicotinamide adenine dinucleotide phosphate by isolated corn mitochondria

Isolated corn (Zea mays L.) mitochondria were found to oxidize reduced nicotinamide adenine dinucleotide phosphate in a KCl reaction medium. This oxidation was dependent on the presence of calcium or phosphate or both. Strontium and manganese substituted for calcium, but magnesium or barium did not. The oxidation of NADPH produced contraction of mitochondria swollen in KCl. Further evidence that the oxidation of NADPH was coupled was observed in respiratory control and adenosine diphosphate-oxygen ratios that were comparable to those reported for reduced nicotinamide adenine dinucleotide. The pathways of electron flow from NADH and NADPH were compared through the addition of electron transport inhibitors. The only difference between the two dinucleotides was that amytal was found to inhibit almost totally the state 3 oxidation of NADPH, but had little effect on the state 3 oxidation of NADH. The hypothetical pathways for electron flow from NADPH are discussed, as are the possible sites of calcium and phosphate stimulation.     

Glycine oxidation in mitochondria isolated from light grown and etiolated plant tissue

Mitochondria were isolated from light grown and dark grown monocotyledonous (wheat- Triticum aestivum and barley- Hordeum vulgare ) and dicotyledonous (pea- Pisum sativum ) plants and their capacity to oxidize glycine was measured. In all of the studied plant species the rate of mitochondrial glycine oxidation was high in light grown leaves. Glycine oxidation in mitochondria from etiolated leaves was also very substantial; the rate of glycine oxidation relative to the oxidation of other substrates was about half as compared to green tissue. In etiolated non-photosynthetic tissues the relative glycine oxidation was only ca 20% of that measured in green leaves. The effect of light on the development of glycine oxidation capacity was studied using etiolated barley which was transferred to light for 6 to 24 h. During this time the rate of glycine oxidation as compared to the oxidation of NADH and malate increased, approaching the ratio observed in light grown leaves. It is concluded that the synthesis of proteins involved in glycine oxidation is regulated both in a light dependent and in a tissue specific manner. Monocotyledonous plants should be very useful for further studies of this aspect due to the relatively small developmental difference between etiolated and light grown leaf tissue.     

Oxidation of External NAD(P)H by Mitochondria from Taproots and Tissue Cultures of Sugar Beet (Beta vulgaris)

The present study compares the exogenous NAD(P)H oxidation and the membrane potential ([delta][psi]) generated in mitochondria isolated from different tissues of an important agricultural crop, sugar beet (Beta vulgaris}. We observed that mitochondria from taproots, cold-stored taproots, and in vitro-grown tissue cultures contain a functional NADH dehydrogenase, whereas only those isolated from tissue cultures displayed a functional NAD(P)H dehydrogenase. It is interesting that the NADH-dependent [delta][psi] of mitochondria from cold-stored taproots and from tissue cultures was not affected by free Ca2+ ions, whereas free Ca2+ was required for the mitochondrial NADPH oxidation by in vitro-grown cells and cytosolic NADH oxidation by mitochondria from fresh taproots. A tentative model accounting for the different response to Ca2+ ions of the NADH dehydrogenase in mitochondria from cold-stored taproots and tissue cultures of B. vulgaris is discussed.     

L-lactate oxidation by skeletal muscle mitochondria

1. Mitochondria isolated from rat skeletal muscle possess lactate dehydrogenase which is involved in direct oxidation of L-lactate in the presence of external NAD. 2. L-lactate oxidation can be stimulated in a reversible manner by ADP. 3. Mitochondrial lactate oxidation is sensitive to oxamate-inhibitor of LDH, alpha-cyano-3-hydroxy-cinnamate-pyruvate translocase inhibitor and respiratory chain inhibitors (rotenone, antimycin A, KCN). 4. In the same conditions the mitochondria did not oxidize pyruvate in the absence of malate, whereas, oxidize pyruvate plus external NADH in an uncoupling manner.     

Partial Purification and Characterization of Three NAD(P)H Dehydrogenases from Beta vulgaris Mitochondria

Mitochondria isolated from the taproot of beet (Beta vulgaris) were used in an effort to identify and partially purify the proteins constituting the exogenous NADH dehydrogenase. Three NAD(P)H dehydrogenases are released from these mitochondria by sonication, and these enzymes were partially purified using fast protein liquid chromatography. One of the enzymes, designated peak I, is capable of oxidizing NADPH and the β form of NADH. The other two activities, peaks II and III, oxidize only β-NADH. All three peaks are insensitive to divalent cation chelators and a complex I inhibitor, rotenone. The major component to peak I is a polypeptide with an apparent molecular mass of approximately 42 kilodaltons. Peak I activity was insensitive to platanetin, a specific inhibitor of the exogenous dehydrogenase, and insensitive to added Ca²⁺ or Mg²⁺. Peak I displayed a broad pH activity profile with an optimum between 7.5 and 8.0 for both NADPH and NADH. Purified peak II gave a single polypeptide of about 32 kilodaltons, had a pH optimum between 7.0 and 7.5, and was slightly stimulated by Ca²⁺ and Mg²⁺. As with peak I, platanetin had no effect on peak II activity. Peak III was not purified completely, but contained two major polypeptides with apparent molecular masses of 55 and 40 kilodaltons. This enzyme was not affected by Ca²⁺ and Mg²⁺, but was inhibited by platanetin. The peak III enzyme had a rather sharp pH optimum of approximately 6.5 to 6.6. The above data indicate that peak III activity is likely the exogenous NADH dehydrogenase.