Influence of the Malate-Aspartate Shuttle on Oxidative Metabolism in Synaptosomes

beta-Methyleneaspartate, a specific inhibitor of aspartate aminotransferase (EC 2.6.1.1.), was used to investigate the role of the malate-aspartate shuttle in rat brain synaptosomes. Incubation of rat brain cytosol, "free" mitochondria, synaptosol, and synaptic mitochondria, with 2 mM beta-methyleneaspartate resulted in inhibition of aspartate aminotransferase by 69%, 67%, 49%, and 76%, respectively. The reconstituted malate-aspartate shuttle of "free" brain mitochondria was inhibited by a similar degree (53%). As a consequence of the inhibition of the aspartate aminotransferase, and hence the malate-aspartate shuttle, the following changes were observed in synaptosomes: decreased glucose oxidation via the pyruvate dehydrogenase reaction and the tricarboxylic acid cycle; decreased acetylcholine synthesis; and an increase in the cytosolic redox state, as measured by the lactate/pyruvate ratio. The main reason for these changes can be attributed to decreased carbon flow through the tricarboxylic acid cycle (i.e., decreased formation of oxaloacetate), rather than as a direct consequence of changes in the NAD+/NADH ratio. Malate/glutamate oxidation in "free" mitochondria was also decreased in the presence of 2 mM beta-methyleneaspartate. This is probably a result of decreased glutamate transport into mitochondria as a result of low levels of aspartate, which are needed for the exchange with glutamate by the energy-dependent glutamate-aspartate translocator.     

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.     

beta-Oxidation and Glyoxylate Cycle Coupled to NADH: Cytochrome c and Ferricyanide Reductases in Glyoxysomes

Glyoxysomes isolated from castor bean (Ricinus communis L., var Hale) endosperm had NADH:ferricyanide reductase and NADH:cytochrome c reductase activities averaging 720 and 140 nanomole electrons/per minute per milligram glyoxysomal protein, respectively. These redox activities were greater than could be attributed to contamination of the glyoxysomal fractions in which 1.4% of the protein was mitochondrial and 5% endoplasmic reticulum. The NADH:ferricyanide reductase activity in the glyoxysomes was greater than the palmitoyl-coenzyme A (CoA) oxidation activity which generated NADH at a rate of 340 nanomole electrons per minute per milligram glyoxysomal protein. Palmitoyl-CoA oxidation could be coupled to ferricyanide or cytochrome c reduction. Complete oxidation of palmitoyl-CoA, yielding 14 nanomole electrons/per nanomole palmitoyl-CoA, was demonstrated with the acceptors, NAL, cytochrome c, and ferricyanide. Malate was also oxidized by glyoxysomes, if acetyl-CoA, ferricyanide, or cytochrome c was present. Glyoxysomal NADH:ferricyanide reductase activity has the capacity to support the combined rates of NADH generation by β-oxidation and the glyoxylate cycle.     

Possible Regulatory Roles of Cytokinins : NADH Oxidation by Peroxidase and a Copper Interaction

Apparently free-base cytokinins can interact with cupric ions in a specific manner. Oxidation of NADH by a horseradish peroxidase system was strongly promoted by such cytokinins provided cupric ions were present. Oxidation was promoted by 5 micromolar kinetin, zeatin, 6-benzylaminopurine (BA), or 6-(Δ²-isopentenylamino)purine (2iP) but not by adenine, 6-methylaminopurine or 6,6-dimethylaminopurine. The 6-methylaminopurine promoted oxidation at 500 micromolar but adenine and 6,6-dimethylaminopurine did not. Activity of the free-base purines correlated well with their activity in cell-division assays. However, addition of methoxymethyl-, cyclohexyl-, or tetrahydropyranyl- at N-9 of BA or of ribosyl- at N-9 of BA, 2iP, kinetin, or zeatin eliminated activity in the peroxidase system. In a nonenzymic system containing cupric ions, all of the bases, including adenine, inhibited the Cu²⁺ -stimulated oxidation of ascorbic acid. As in the peroxidase system, the N-9 derivatives were inactive. The cytokinin promotion of NADH oxidation by peroxidase may result from an interaction of the hormones with copper, with peroxidase conferring a specificity similar to the cytokinin specificity observed in growth and development.     

NADH Oxidation by Mitochondria from the Thermogenic Plant Arum orientale

The enzyme content of the mitochondrial respiratory chain was investigated in the heat-producing plant Arum orientale. It is shown that mitochondria isolated from thermogenic tissues of this plant (with respect to non-thermogenic tissues of A. orientale or to Zea mays) demonstrate significantly elevated levels of activities of two non-coupled NADH dehydrogenases oxidizing intramitochondrial and cytoplasmic NADH pools. It is postulated that operation of a completely non-coupled respiratory chain consisting of non-coupled NADH:quinone oxidoreductases and cyanide-resistant alternative quinol-oxidase is the main mechanism of heat production in thermogenic plants.     

Ethanol Biosensors and Electrochemical Oxidation of NADH

Comparative studies of the electrochemical oxidation of reduced nicotinamide coenzyme (NADH) at the surfaces of chemically modified graphite paste electrodes (CMEs) are reported. Three different electroactive materials, tetracyanoquinodimethane (TCNQ), tetrathiafulvalene (TTF), and dimethyl ferrocene (dmFc), were used to construct three different chemically modified paste electrodes. The oxidation of NADH was examined on the basis of cyclic voltammetric measurements. The results show that all three mediators (TCNQ, TTF, and dmFc) behave as efficient mediators of the oxidation of NADH. The typical response curves of NADH at the CMEs surfaces are reported. Incorporating alcohol dehydrogenase and electroactive materials (TCNQ, TTF, and dmFc) within the graphite paste electrodes has led to the development of ethanol biosensors. Typical response curves for the ethanol analysis are reported. Comparative studies on the mediated electrochemical responses of the biosensors to ethanol are discussed.     

Reactions of NADH Oxidation by Tetrazolium and Ubiquinone Catalyzed by Yeast Alcohol Dehydrogenase

The processes of NADH oxidation by p-NTF violet and ubiquinone catalyzed by isolated yeast alcohol dehydrogenase in aqueous and water-alcohol buffer solutions were studied. In the presence of p-NTF in aqueous solution at a pH of 6–7, NADH oxidation was extremely slow due to inhibition of the enzyme by the remaining enzyme-bound hydrophobic product, formazan, which forms during the reduction of p-Nitrotetrazolium. However, when the medium was alkalinized to a pH of 8–9 or when alcohol (ethanol or isopropanol) was added, formazan was desorbed from the enzyme, leading to an increase in the NADH oxidation rate. It was assumed that this redox reaction can be used as the basis for colorimetric measurement of the activity of different alcohol dehydrogenases. Tetrazolium reduction by alcohol was not observed at any value within the entire pH range. NADH oxidation in the presence of the enzyme and ubiquinone was also slow, even with the addition of alcohol, but its rate increased when the medium was acidified to a pH of 5.5–6. When a Tris-phosphate buffer was replaced with HEPES, a quasi-vibrational process was observed: NADH oxidization with ubiquinone to NAD⁺ and its subsequent reverse recovery with alcohol to NADH.     

Oxidation of NADH by hypocotyl segments from soybean is stimulated by 2,4-D

Sections cut from regions of cell elongation of hypocotyls of dark-grown soybean seedlings oxidized externally supplied NADH as estimated from the decrease in A₃₄₀ measured spectrophotometrically. The oxidation of NADH by 1-cm sections was stimulated 1.5- to 2-fold by 1 μM of the synthetic auxin, 2,4-dichlorophenoxyacetic acid (2,4-D). 2,4-D-Stimulated oxidation of NADH was resistant to cyanide. Stimulations were also given by the naturally occurring auxin, indole-3-acetic acid (IAA) but not by the growth inactive 2,4-D analog 2,3-dichlorophenoxyacetic acid (2,3-D) and the growth inactive β-naphthaleneacetic acid (β-NAA). Since NADH is a membrane impermeant substrate, the findings confirm studies with inside-out and right-side-out vesicles that show the 2,4-D-stimulated NADH oxidase to be located at the external cell surface. Cut surfaces are not responsible for the activity as shown by experiments with lanolin-sealed sections. The external NADH oxidase measurements do not require special equipment and exhibit characteristics normally associated with enzyme-catalyzed reactions.     

Oxidation of cytosolic NADH by the malate-aspartate shuttle in MC29 hepatoma cells

The malate-aspartate shuttle activity for the reoxidation of cytosolic NADH was studied in MC29 avian hepatoma cells whose mitochondria preferentially utilized glutamine and produced aspartate for ATP formation. The tumour cells showed reoxidation of NADH, as evidenced by the accumulation of pyruvate, when incubated aerobically with L-lactate. The involvement of the respiratory chain and transaminase in the process was demonstrated by the addition of specific inhibitors. When the tumour cells were cultured in Eagle's medium with aminooxyacetate or in the absence of glutamine, a marked reduction in the cellular NAD/NADH ratio was observed. These results indicate that the malate-aspartate shuttle was actively functioning in the tumour cells and that this hepatoma may provide a suitable system for the investigation of the bioenergetics of malignant cells.     

Oxidation of NADH by plant mitochondria: Kinetics and effects of calcium ions

The kinetics of NADH oxidation by the outer membrane electron transport system of intact beetroot (Beta vulgaris L.) mitochondria were investigated. Very different values for V_max and the K_m for NADH were obtained when either antimycin A-insensitive NADH-cytochrome c activity (V_max= 31 ± 2.5 nmol cytochrome c (mg protein)^?1 min^?1; K_m= 3.1 ± 0.8 μM) or antimycin A-insensitive NADH-ferricyanide activity (V_max= 1.7 ± 0.7 μmol ferricyanide (mg protein)^?1 min^?1; K_m= 83 ± 20 μM) were measured. As ferricyanide is believed to accept electrons closer to the NADH binding site than cytochrome c, it was concluded that 83 ± 20 μM NADH represented a more accurate estimate of the binding affinity of the outer membrane dehydrogenase for NADH. The low K_m determined with NADH-cytochrome c activity may be due to a limitation in electron flow through the components of the outer membrane electron transport chain. The K_m for NADH of the externally-facing inner membrane NADH dehydrogenase of pea leaf (Pisum sativum L. cv. Massey Gem) mitochondria was 26.7 ± 4.3 μM when oxygen was the electron acceptor. At an NADH concentration at which the inner membrane dehydrogenase should predominate, the Ca²⁺ chelator, ethyleneglycol-(β-aminoethylether)-N,N,-tetraacetic acid (EGTA), inhibited the oxidation of NADH through to oxygen and to the ubiquinone-10 analogues, duroquinone and ubiquinone-1, but had no effect on the antimycin A-insensitive ferricyanide reduction. It is concluded that the site of action of Ca²⁺ involves the interaction of the enzyme with ubiquinone and not with NADH.     

A Kinetic Study on the Phenothiazine Dependent Oxidation of NADH by Bovine Ceruloplasmin

Tranquillizing drugs of the phenothiazine class form charge-transfer complexes with a ceruloplasmin-Cu(II) ion [De Mol NJ. 1985 Biochim Pharmacol 34, 2605–2609], the interaction resulting in a stimulatory effect on the ceruloplasmin catalyzed oxidation of catecholamines and NADH; the latter used as substrate in the present study. A good correlation between stability of the enzyme–drug complex and electron donor ability of the phenothiazine molecule was obtained for drugs with an aliphatic propyl side chain in 10-position (promazine > chlorpromazine > triflupromazine). The hydrofobic methyl group in the side chain of levomepromazine appeared to reduce the stability. A simple correlation between specific efficiency of the enzyme–drug complex and electron donor ability was not obtained (chlorpromazine > promazine = levomepromazine > triflupromazine). The K_m-values, characterizing the reaction between NADH and the different enzyme–drug complexes, were estimated. The data suggest that the enzyme–chlorpromazine complex has the best affinity for NADH. The stimulatory effect of levomepromazine closely followed that of promazine.     

Glyoxysomes in megagamethophyte of germinating ponderosa pine seeds

Decoated ponderosa pine (Pinus ponderosa Laws) seeds contained 40% lipids, which were mainly stored in megagametophytic tissue and were utilized or converted to sugars via the glyoxylate cycle during germination. Mitochondria and glyoxysomes were isolated from the tissue by sucrose density gradient centrifugation at different stages of germination. It was found that isocitrate lyase, malate synthase, and catalase were mainly bound in glyoxysomes. Aconitase and fumarase were chiefly localized in mitochondria, whereas citrate synthase was common for both. Both organelles increased in quantity and specific activity of their respective marker enzymes with the advancement of germination. When the megagametophyte was exhausted at the end of germination, the quantity of these organelles and the activity of their marker enzymes decreased abruptly. At the stage of highest lipolysis, the isolated mitochondria and glyoxysomes were able to synthesize protein from labeled amino acids. Both organellar fractions contained RNA and DNA. Some degree of autonomy in glyoxysomes is indicated.     

Oxidation of NADH by chloramines and chloramides and its activation by iodide and by tertiary amines

Irreversible oxidation of reduced nicotinamide nucleotides by neutrophil-derived halogen oxidants (HOCl, chloramines, HOBr, etc.) is likely to be a highly lethal process, because of the essential role of NAD(P)H in important cell functions such as mitochondrial electron transport, and control of the cellular thiol redox state by NADPH-dependent glutathione reductase. Chloramines (chloramine-T, NH(2)Cl, etc.) and N-chloramides (N-chlorinated cyclopeptides) react with NADH to generate the same products as HOCl, i.e., pyridine chlorohydrins, as judged from characteristic changes in the NADH absorption spectrum. Compared with the fast oxidation of NADH by HOCl, k approximately 3 x 10(5) M(-1) s(-1) at pH 7.2, the oxidation by chloramines is about five orders of magnitude slower; that by chloramides is about four orders of magnitude slower. Apparent rate constants for oxidation of NADH by chloramines increase with increasing proton or buffer concentration, consistent with general acid catalysis, but oxidation by chloramides proceeds with pH-independent kinetics. In presence of iodide the oxidation of NADH by chloramines or chloramides is faster by at least two orders of magnitude; this is due to reaction of iodide with the N-halogen to give HOI/I(2), the most reactive and selective oxidant for NADH among HOX species. Quinuclidine derivatives (QN) like 3-chloroquinuclidine and quinine are capable of catalyzing the irreversible degradation of NADH by HOCl and by chloramines; QN(+)Cl, the chain carrier of the catalytic cycle, is even more reactive toward NADH than HOCl/ClO(-) at physiological pH. Oxidation of NADH by NH(2)Br proceeds by fast, but complex, biphasic kinetics. A compilation of rate constants for interactions of reactive halogen species with various substrates is presented and the concept of selective reactivity of N-halogens is discussed.     

Oxidation of cytosolic NADH by the malate-aspartate shuttle in HuH13 human hepatoma cells.

1. The reoxidation of cytosolic NADH was studied in a line of human hepatoma cells (HuH13) whose mitochondria preferentially utilized glutamine for ATP formation. 2. The tumor cells showed mitochondrial reoxidation of NADH, as evidenced by the accumulation of pyruvate, when incubated aerobically with L-lactate. The involvement of the respiratory chain was demonstrated by the addition of specific inhibitors. 3. Glutamine oxidation proceeded in the tumor mitochondria exclusively via a pathway involving transamination. Malate stimulated aspartate production from glutamine. 4. When the tumor cells were cultured in Eagle's medium with aminooxyacetate or in the absence of glutamine, a marked reduction in the cellular NAD/NADH ratio was observed. 5. These results indicate that the malate-aspartate shuttle was functioning in the tumor cells.     

Oxidation of NADH by melanin: effect of UV light and copper ions.

The oxidation reaction of NADH with synthetic melanin from L-dopa was investigated under various physicochemical conditions both by spectrophotometric measurements and ESR spectroscopy. The different amounts of NADH oxidized and the effects on the formation and decay of melanin free radicals were compared. Some hypotheses on a common physical mechanism involved in electron transfer reaction and in electron excitation through a liquid-solid interface are presented.     

Beta-Oxidation in Glyoxysomes from Euglena*

SYNOPSIS. We demonstrated previously the presence of glyoxysomes containing the glyoxylate cycle enzymes in Euglena gracilis grown in the dark on ethanol. We have now established that the glyoxysomes of Euglena grown on hexanoate also contain the following enzymes of the pathway for β-oxidation of fatty acids: hexanoyl-CoA synthetase, 3-β-hydroxyacyl-CoA dehydrogenase and thiolase. Estimations of specific activities indicate that these enzymes are over 20 times as active in glyoxysomes as they are in mitochondria, suggesting that the β-oxidation of fatty acids occurs almost entirely in Euglena glyoxysomes under these conditions. Thus, the entire portion of the gluconeogenic pathway from fatty acid to succinate is localized in the glyoxysome of Euglena.     

The Role of Phosphate Anions in Autoinduced and Photoinduced Oxidation of NADH

Biophysics - The effects of mono- and disubstituted phosphates on the photolysis reaction of reduced nicotinamide adenine dinucleotide (NADH) in a frozen (77 K) aqueous solution were studied by...