Oxaloacetate inhibition of succinate oxidation in tightly coupled liver mitochondria with ferricyanide as an electron acceptor

When ferricyanide is used as an artificial electron acceptor, succinate oxidation by tightly coupled liver mitochondria becomes inhibited after 1–3 min. No inhibition occurs in the presence of rotenone or glutamate establishing that oxaloacetate causes the inhibtion. Oxygen consumption by mitochondria oxidizing succinate does not become inhibited in the absence of rotenone suggesting that oxaloacetate accumulates to a greater extent when ferricyanide is added than when oxygen is the terminal acceptor. Higher levels of oxaloacetate in the ferricyanide reaction are apparently due to an increased rate of synthesis rather than a decreased rate of removal. Thus it appears that when succinate is the substrate and oxygen the terminal acceptor a control mechanism exists which blocks oxidation of malate. When ferricyanide is added as an artificial electron acceptor this control is lost and oxaloacetate accumulates to inhibit succinate oxidation.     

Effects of rotenoids on isolated plant mitochondria

The effects of several rotenoids have been studied on potato (Solanum tuberosum L.) tuber and etiolated mung bean (Phaseolus aureus Roxb.) hypocotyls mitochondria. The selective inhibition of mitochondrial complex I is characterized by several tests: (a) no effect can be observed on exogenous NADH or succinate oxidation; (b) malate oxidation is inhibited at pH 7.5; (c) one-third decrease of ADP/O ratio appears during malate oxidation at pH 6.5 or during α-ketoglutarate, citrate, or pyruvate oxidation at a pH about 7; (d) during malate oxidation at pH 6.5, a transient inhibition appears which can be maintained by addition of exogenous oxaloacetate; (e) in potato mitochondria, the inhibition of malate oxidation disappears at pH 6.5 when NAD⁺ is added. Then, a one-third decrease of the ADP/O ratio can be measured.

Such a selective inhibition of complex I is obtained with deguelin, tephrosin, elliptone, OH-12 rotenone, and almost all the rotenoids extracted from Derris roots. The presence of the rings A, B, C, D, E seems to be necessary for the selective inhibition. Opening of the E ring and hydroxylation of the 9 position (rot-2′-enoic acid) give a rotenoid derivative with multisite inhibitory activities on flavoproteins, which are quite comparable to those of common flavonoids such as kaempferol (Ravanel et al. 1982 Plant Physiol 69: 375-378).

     

Correlation of the effects of citric acid cycle metabolites on succinate oxidation by rat liver mitochondria and submitochondrial particles.

1. Succinate dehydrogenase is inhibited by citrate and beta-hydroxy-butyrate in a complex manner, both in mitochondria and submitochondrial particles. Kinetics of inhibition in the particles points to a competitive component in the mechanism involved. 2. Pyruvate, alpha-ketoglutarate, malate, and glutamate stimulate oxidation of succinate by mitochondria. 3. Stimulation by alpha-ketoglutarate and glutamate is not influenced by the presence of rotenone. 4. Stimulation by pyruvate is higher in the absence of rotenone and increases significantly in the presence of K+ and valinomycin. Pyruvate supplies in mitochondria reducing equivalents for malate dehydrogenase operating in the reverse direction-reduction of oxaloacetate to malate. 5. Stimulation by malate is higher in the presence of rotenone.     

The Effect of Respiratory Inhibitors on NADH, Succinate and Malate Oxidation in Corn Mitochondria

The effect of a series of respiratory inhibitors on the oxidation of NADH in state 4 and state 3 conditions was studied with corn shoot mitochondria. Comparisons were made using malate and succinate as substrates. The inhibitors, rotenone, amytal, antimycin A and cyanide, inhibited oxidation of NADH in state 3 but rotenone and amytal did not inhibit oxidation in state 4. The inhibition by antimycin A was partially overcome by the presence of cytochrome c. The results indicate the presence of alternative pathways available for NADH oxidation depending on the metabolic condition of the mitochondria. Under state 4 conditions, NADH oxidation bypasses the amytal and rotenone sensitive sites but under state 3 conditions a component of the NADH respiration appears to be oxidized by an internal pathway which is sensitive to these inhibitors. Still a third pathway for NADH oxidation is dependent on the addition of cytochrome c and is insensitive to antimycin A. Succinate oxidation was sensitive to cyanide and antimycin A under both state 4 and state 3 conditions as well as amytal and rotenone under state 3 conditions but was not inhibited by amytal and rotenone under state 4 conditions. Malate oxidation was inhibited by cyanide, rotenone and amytal under both state 4 and state 3 conditions. Antimycin A inhibited state 3 but did not appreciably alter state 4 rates of malate oxidation. With all substrates tested inhibition by antimycin A was greatly facilitated by preswelling the mitochondria for 10 min. This was interpreted to indicate that swelling increases the accessibility of antimycin A to the site of inhibition.     

Evidence that the blockade of mitochondrial respiration by the neurotoxin 1-methyl-4-phenylpyridinium (MPP+) involves binding at the same site as the respiratory inhibitor, rotenone

It has been postulated that 1-methyl-4-phenylpyridinium (MPP+) blocks mitochondrial respiration by combining at the same site as rotenone, a potent inhibitor of NADH oxidation in mitochondria, known to act at the junction of NADH dehydrogenase and coenzyme Q (CoQ). The present experiments show that MPP+ and two of its analogs indeed act in a concentration dependent manner to prevent the binding of [14C]-rotenone to submitochondrial particles (ETP) and significantly decrease the inhibition of electron transport caused by rotenone. It therefore appears that MPP+ binds at the same site as rotenone or an adjacent site, supporting the hypothesis that its neurotoxic action is due to the inhibition of mitochondrial respiration.     

Correlation of the effects of citric acid cycle metabolites on succinate oxidation by rat liver mitochondria and submitochondrial particles

1. Succinate dehydrogenase is inhibited by citrate and β-hydroxybutyrate in a complex manner, both in mitochondria and submitochondrial particles. Kinetics of inhibition in the particles points to a competitive component in the mechanism involved.
2. Pyruvate, α-ketoglutarate, malate, and glutamate stimulate oxidation of succinate by mitochondria.
3. Stimulation by α-ketoglutarate and glutamate is not influenced by the presence of rotenone.
4. Stimulation by pyruvate is higher in the absence of rotenone and increases significantly in the presence of K⁺ and valinomycin. Pyruvate supplies in mitochondria reducing equivalents for malate dehydrogenase operating in the reverse direction-reduction of oxaloacetate to malate.
5. Stimulation by malate is higher in the presence of rotenone.

     

Regulation of succinate oxidation by NAD+ in mitochondria purified from potato tubers

NAD⁺ supplied to purified Solanum tuberosum mitochondria caused progressive inhibition of succinate oxidation in State 3. This inhibition was especially pronounced at alkaline pH and at low succinate concentrations. Glutamate counteracted the inhibition. NAD⁺ promoted oxaloacetate accumulation in State 3; supplied oxaloacetate inhibited O₂ uptake in the presence of succinate much more severely in State 3 than in State 4. NAD reduction linked to succinate oxidation by ATP-dependent reverse electron transport was likewise inhibited by oxaloacetate. We conclude that NAD⁺-induced inhibition of succinate oxidation is due to an inhibition of succinate dehydrogenase resulting from increased accumulation of oxaloacetate generated from malate oxidation via malate dehydrogenase. The results are discussed in the context of the known regulatory characteristics of plant succinate dehydrogenase.     

Matrix NADH dehydrogenases of plant mitochondria and sites of quinone reduction by complex I.

In order to distinguish the pathways involved in the oxidation of matrix NADH in plant mitochondria, the oxidation of NADH and nicotinamide hypoxanthine dinucleotide (reduced form) was investigated in submitochondrial particles prepared from beetroot (Beta vulgaris L. cv. Derwent Globe) and soybeans (Glycine max L. cv. Bragg). Nicotinamide-hypoxanthine-dinucleotide(reduced form)-oxidase activity was more strongly inhibited by rotenone than the NADH-oxidase activity but both of the rotenone-inhibited activities could be stimulated by adding ubiquinone-1. The corresponding ubiquinone-1-reductase activities were inhibited by rotenone (to 69%) and further inhibited by N,N'-dicyclohexylcarbodiimide (to 79%), whilst the K3Fe(CN)6-reductase activities were not sensitive to either rotenone or N,N'-dicyclohexylcarbodiimide. Immunological analysis of mitochondrial proteins using an antiserum raised against purified beetroot complex I indicated very few differences between soybean and fresh and aged beetroot mitochondria, despite their varying sensitivities to rotenone. We confirm that there are two dehydrogenases capable of oxidising internal NADH and that only one of these, namely complex I, is inhibited by rotenone. Further, we conclude that complex I has two potential sites of quinone reduction, both sensitive to N,N'-dicyclohexycarbodiimide inhibition but only one of which is sensitive to rotenone inhibition.     

The effect of rotenone on respiration in pea cotyledon mitochondria

Respiration utilizing NAD-linked substrates in mitochondria isolated from cotyledons of etiolated peas (Pisum sativum L. var. Homesteader) by sucrose density gradient centrifugation exhibited resistance to rotenone. The inhibited rate of α-ketoglutarate oxidation was equivalent to the recovered rate of malate oxidation. (The recovered rate is the rate following the transient inhibition by rotenone.) The inhibitory effect of rotenone on malate oxidation increased with increasing respiratory control ratios as the mitochondria developed. The cyanide-resistant and rotenone-resistant pathways followed different courses of development as cotyledons aged. The rotenone-resistant pathway transferred reducing equivalents to the cyanide-sensitive pathway. Malic enzyme was found to be inhibited competitively with respect to NAD by rotenone concentrations as low as 1.67 micromolar. In pea cotyledon mitochondria, rotenone was transformed into elliptone. This reduced its inhibitory effect on intact mitochondria. Malate dehydrogenase was not affected by rotenone or elliptone. However, elliptone inhibited malic enzyme to the same extent that rotenone did when NAD was the cofactor. The products of malate oxidation reflected the interaction between malic enzyme and malate dehydrogenase. Rotenone also inhibited the NADH dehydrogenase associated with malate dehydrogenase. Thus, rotenone seemed to exert its inhibitory effect on two enzymes of the electron transport chain of pea cotyledon mitochondria.     

Metabolite fluxes across the inner membrane of plant mitochondria — inhibition by phthalonic acid

Transport and oxidation-reduction of citrate, 2-oxoglutarate and oxaloacetate by mitochondria isolated from thermogenic (Arum maculatum, Sauromatum guttatum spadices), green leaf (Pisum sativum) or etiolated (Phaseolus aureus, Helianthus tuberosus) plant tissues was found to be inhibited by phthalonic acid. No inhibition was found for NADH oxidation, glutamate, succinate or glycine transport and oxidation and malate transport. The much greater sensitivity of citrate oxidation to phthalonate inhibition compared with that of 2-oxoglutarate indicated that different carriers were involved, neither of which appeared to be rate-limiting for oxidation. Fluxes of oxaloacetate, and their sensitivity to phthalonate, indicated that this keto acid may use either the same carrier as 2-oxoglutarate or an oxaloacetate-specific carrier.Abbreviation PTA phthalonic acid     

Studies on the oxidation of isobutyrylcarnitine by beef and rat liver mitochondria.

Mitochondria from beef liver oxidize isobutyrylcarnitine at approximately 50% the rate of succinate in the presence of rotenone. However, the oxidation rate of isobutyryl coenzyme A in the presence of l(-)-carnitine is very low and can be negligible in both rat and beef liver mitochondria. The limited stimulation of isobutyryl-CoA oxidation by l(-)-carnitine appears to be due to inhibition of isobutyrylcarnitine translocation rather than lack of formation of isobutyrylcarnitine. This conclusion is supported by the fact that: 1) isobutyrylcarnitine oxidation is inhibited by l(-)-carnitine; 2) some oxidation of isobutyryl-CoA is obtained when a low concentration (50 microM) of l(-)-carnitine is used; and 3) under conditions of high isobutyryl-coenzyme A and l(-)-carnitine concentrations (1 mM), isobutyryl-carnitine is produced in near theoretical amounts by these rat liver mitochondria. Other studies demonstrated that less than 25% of the carnitine isobutyryl transferase activity of beef liver mitochondria and rat liver mitochondria is located on the cytosol side of the acylcoenzyme A barrier of these mitochondria.     

Formation of superoxide radicals in the mitochondria of skeletal muscle

The superoxide-dependent oxidation of adrenaline by skeletal muscle mitochondria (maximal inhibition by superoxide dismutase from 50 to 80%) is described. The oxidation reaction is initiated by antimycin A but not by rotenone. It was assumed that the main source of superoxide radicals in skeletal muscle mitochondria is the site of the respiratory chain between the rotenone and antimycin block. It was found that skeletal muscle mitochondria are characterized by a higher rate of superoxide anion formation and by a lower activity of superoxide dismutase as compared to heart mitochondria.     

Malate oxidation by mitochondrial succinate:ubiquinone-reductase

Succinate:ubiquinone reductase was shown to catalyze the oxidation of L- and D-stereoisomers of malate by artificial electron acceptors and ubiquinone. The rate of malate oxidation by succinate:ubiquinone reductase is by two orders of magnitude lower than that for the natural substrate--succinate. The values of kinetic constants for the oxidation of D- and L-stereoisomers of malate are equal to: V infinity = 0.1 mumol/min/mg protein, Km = 2 mM and V infinity = 0.05 mumol/min/mg protein, Km = 2 mM, respectively. The malate dehydrogenase activity is fully inhibited by the inhibitors of the dicarboxylate-binding site of the enzyme, i.e., N-ethylmaleimide and malonate and is practically insensitive to carboxin, a specific inhibitor of the ubiquinone-binding center. The enol form of oxaloacetate was shown to be the product of malate oxidation by succinate:ubiquinone reductase. The kinetics of inhibition of the enzyme activity by the ketone and enol forms of oxaloacetate was studied. Both forms of oxaloacetate effectively inhibit the succinate:ubiquinone reductase reaction.     

紫云英根瘤菌109菌株的氢氧化电子传递链

H_2还原减去O_2氧化的差示光谱显示424,522,552,560,603nm峰,鱼腾酮(反竞争性抑制),DBMIB,HQNO,抗霉素A,氰化钠和叠氮化钠(非竞争性抑制)明显抑制吸氢活性,表明细胞色素c,b和a分别参与氢氧化的电子传递。以Dixon作图来确定抑制剂在电子传递链中结合位点数目,鱼腾酮和DBMIB为单位点结合,HQNO和氰化物为双位点结合,HQNO所引起的部份抑制,可使对氰化钠敏感的结合位点消逝。鱼腾酮与HQNO同时存在时,其叠加或累积抑制效果表明,两种类型的细胞色素b参与氢氧化的电子传递,由H_2到O_2的电子传递于细胞色素b处分叉,对氰化物抑制敏感性也有所不同。     

The Effect of Exogenous Nicotinamide Adenine Dinucleotide on the Oxidation of Nicotinamide Adenine Dinucleotide-linked Substrates by Isolated Plant Mitochondria

The oxidation of malate, citrate, and α-ketoglutarate by cauliflower (Brassica oleacea L.) bud mitochondria was inhibited by rotenone. This inhibition was relieved upon addition of NAD⁺ to the medium, and ADP/O values were lowered to less than 2 when both rotenone and NAD⁺ were present. Dinitrophenol did not affect the relief of rotenone inhibition by exogenous NAD⁺.     

Choline oxidation and choline dehydrogenase

The oxidation of choline by both freshly prepared and aged rat liver mitochondria is inhibited by amytal. Whereas rotenone inhibits choline-cytochromec reductase only in the case of freshly prepared mitochondria, the extent of inhibition is influenced by preincubation, but the inhibition is not secondary to the inhibited oxidation of betaine aldehyde, the product of choline oxidation. Evidence shows that rotenone is able to inhibit the swelling of rat liver mitochondria and the inhibition of choline-cytochromec reductase by rotenone is related to the inhibition of mitochondrial swelling. Nine inhibitors of choline dehydrogenase have been reported. Among those, some belong to the category of acetylcholine esterase inhibitor. In view of the structure of those inhibitors, it seems quite likely that there is an anionic site at the active center of choline dehydrogenase. Purification of choline dehydrogenase in its native form has been accomplished by solubilization with Lubrol WX, hydroxyapatite, and DEAE-Sepharose chromatography and sucrose gradient ultracentrifugation. The preparation is pure as judged by SDS-PAGE and Ultrogel AcA 34 column chromatography. The molecular weight determined by SDS-PAGE is approximately 61,000. There is 0.23 mg phospholipid/mg protein and the Stokes' radius of protein-Lubrol-phospholipid mixed micelles is about 59 A.     

Calcium uptake by bovine epididymal spermatozoa is regulated by the redox state of the mitochondrial pyridine nucleotides

Immature caput epididymal sperm accumulate calcium from exogenous sources at a rate 2- to 4-fold greater than mature caudal sperm. Calcium accumulation by these cells, however, is maximal in the presence of lactate as external substrate. This stimulation of calcium uptake by optimum levels of lactate (0.8-1.0 mM) is about 5-fold in caput and 2-fold in caudal sperm compared to values observed with glucose as substrate. Calcium accumulation by intact sperm is almost entirely mitochondrial as evidenced by the inhibition of uptake by rotenone, antimycin, and ruthenium red. The differences in the ability of the various substrates in sustaining calcium uptake appeared to be related to their ability to generate NADH (nicotinamide adenine dinucleotide). Previous reports have documented that mitochondrial calcium accumulation in several somatic cells is regulated by the oxidation state of mitochondrial NADH. A similar situation obtains for bovine epididymal sperm since calcium uptake sustained by site III oxidation of ascorbate in the presence of tetramethyl phenylenediamine and rotenone was also stimulated by NADH-producing substrates, including lactate, and inhibited by substrates generating NAD+ (nicotinamide adenine dinucleotide, oxidized form). Further, calcium uptake by digitonin-permeabilized sperm in the presence of succinate was stimulated when NADH oxidation was inhibited by rotenone. The compounds alpha-keto butyric, valeric, and caproic acids, which generate NAD+, inhibited the maximal calcium uptake observed in the presence of succinate and rotenone, and the hydroxy acids lactate and beta-hydroxybutyrate reversed this inhibition. These results document the regulation of sperm calcium accumulation by the physiological substrate lactate, emphasize the importance of mitochondria in the accumulation of calcium by bovine epididymal sperm, and suggest that the mitochondrial location of the isozyme LDH-X in mammalian sperm may be involved in the regulation of calcium accumulation.     

Effect of ethylmaleimide on the transport of Ca+ and K+ ions across mitochondrial membranes

As already reported, it has been found that the gradient of protons, set up across the inner membrane during the Ca2+ uptake by rat liver mitochondria, can be completely reversed by the addition of NEM. Identical results have been obtained by following the energy dependent K+ uptake. In these last conditions, the rate of H+ efflux supported by succinate oxidation is greatly enhanced only when NEM is added after rotenone. It is proposed that the increased rate other than to the inhibition of Pi uptake, as suggested by Reynafarje and Lehninger, could also be ascribed to a further decrease in the energetic level of the membrane as well as to an increased rate of succinate-Pi exchange diffusion reaction induced by NEM. A possible direct effect of NEM on succinate oxidation has been also considered to account for the inhibition observed when it is added before rotenone.     

Effect of bicarbonate and oxaloacetate on malate oxidation by spinach leaf mitochondria

Mitochondria isolated from spinach leaves oxidized malate by both a NAD⁺-linked malic enzyme and malate dehydrogenase. In the presence of sodium arsenite the accumulation of oxaloacetate and pyruvate during malate oxidation was strongly dependent on the malate concentration, the pH in the reaction medium and the metabolic state condition.Bicarbonate, especially at alkaline pH, inhibited the decarboxylation of malate by the NAD⁺-linked malic enzyme in vitro and in vivo. Analysis of the reaction products showed that with 15 mM bicarbonate, spinach leaf mitochondria excreted almost exclusively oxaloacetate.The inhibition by oxaloacetate of malate oxidation by spinach leaf mitochondria was strongly dependent on malate concentration, the pH in the reaction medium and on the metabolic state condition.The data were interpreted as indicating that: (a) the concentration of oxaloacetate on both sides of the inner mitochondrial membrane governed the efflux and influx of oxaloacetate; (b) the NAD⁺/NADH ratio played an important role in regulating malate oxidation in plant mitochondria; (c) both enzymes (malate dehydrogenase and NAD⁺-linked malic enzyme) were competing at the level of the pyridine nucleotide pool, and (d) the NAD⁺-linked malic enzyme provided NADH for the reversal of the reaction catalyzed by the malate dehydrogenase.     

Glucose alleviates ammonia-induced inhibition of short-chain fatty acid metabolism in rat colonic epithelial cells

Ammonia decreased metabolism by rat colonic epithelial cells of butyrate and acetate to CO2 and ketones but increased oxidation of glucose and glutamine. Ammonia decreased cellular concentrations of oxaloacetate for all substrates evaluated. The extent to which butyrate carbon was oxidized to CO2 after entering the tricarboxylic acid (TCA) cycle was not significantly influenced by ammonia, suggesting there was no major shift toward efflux of carbon from the TCA cycle. Ammonia reduced entry of butyrate carbon into the TCA cycle, and the proportion of CoA esterified with acetate and butyrate correlated positively with the production of CO2 and ketone bodies. Also, ammonia reduced oxidation of propionate but had no effect on oxidation of 3-hydroxybutyrate. Inclusion of glucose, lactate, or glutamine with butyrate and acetate counteracted the ability of ammonia to decrease their oxidation. In rat colonocytes, it appears that ammonia suppresses short-chain fatty acid (SCFA) oxidation by inhibiting a step before or during their activation. This inhibition is alleviated by glucose and other energy-generating compounds. These results suggest that ammonia may only affect SCFA metabolism in vivo when glucose availability is compromised.