Remodeling of the vascular tunica media is essential for development of collateral vessels in the canine heart

A method to study the export of citric acid cycle intermediates from rat liver mitochondria supplied with various individual substrates or combinations of substrates was designed to focus on the role of mitochondria in anaplerosis and cataplerosis. Under most conditions malate, citrate, and aspartate were exported in far higher amounts than isocitrate and alpha-ketoglutarate. In the presence of pyruvate alone or pyruvate in combination with most other substrates, citrate export equaled or was only slightly less than malate export. This contrasts with pancreatic islet mitochondria where citrate export is unaffected by many substrates. Malate and succinate potentiated pyruvate-induced citrate export and succinate caused massive malate export from liver mitochondria. Heart mitochondria, which possess very little or no pyruvate carboxylase, unlike liver and pancreatic islet mitochondria, did not produce malate from pyruvate. Heart mitochondria produced malate, but not citrate, from succinate. The results indicate that liver mitochondria export a larger number of metabolites from a wider range of substrates than do islet or heart mitochondria. This may reflect the multiple roles of the liver in body metabolism versus the specialized roles of the islet cell and heart.     

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.     

EDTA-dependent assimilation of glucose and organic acids by an EDTA-degrading bacterium

Bacterial strain VKM B-2445 is characterized by ethylenediaminetetraacetate (EDTA) requirement for cell growth. This strain could not grow on glucose and organic acids as the sole sources of carbon and energy, but it was able to metabolize these substrates added to EDTA medium. EDTA initiated assimilation of glucose, succinate, fumarate, malate, and citrate and supplied nitrogen for the biomass production from these substrates. Utilization of primarily nongrowth substrates by strain VKM B-2445 started when EDTA was exhausted or at least considerably degraded.     

Regulation of insulin release by factors that also modify glutamate dehydrogenase

Leucine and monomethyl succinate initiate insulin release, and glutamine potentiates leucine-induced insulin release. Alanine enhances and malate inhibits leucine plus glutamine-induced insulin release. The insulinotropic effect of leucine is at least in part secondary to its ability to activate glutamate oxidation by glutamate dehydrogenase (Sener, A., Malaisse-Lagae, F., and Malaisse, W. J. (1981) Proc. Natl. Acad. Sci. U. S. A. 78, 5460-5464). The effect of these other amino acids or Krebs cycle intermediates on insulin release also correlates with their effects on glutamate dehydrogenase and their ability to regulate inhibition of this enzyme by alpha-ketoglutarate. For example, glutamine enhances insulin release and islet glutamate dehydrogenase activity only in the presence of leucine. This could be because leucine, especially in the presence of alpha-ketoglutarate, increases the Km of glutamate and converts alpha-ketoglutarate from a noncompetitive to a competitive inhibitor of glutamate. Thus, in the presence of leucine, this enzyme is more responsive to high levels of glutamate and less responsive to inhibition by alpha-ketoglutarate. Malate could decrease and alanine could increase insulin release because malate increases the generation of alpha-ketoglutarate in islet mitochondria via the combined malate dehydrogenase-aspartate aminotransferase reaction, and alanine could decrease the level of alpha-ketoglutarate via the alanine transaminase reaction. Monomethyl succinate alone is as stimulatory of insulin release as leucine alone, and glutamine enhances the action of both. Succinyl coenzyme A, leucine, and GTP are all bound in the same region on glutamate dehydrogenase, where GTP is a potent inhibitor and succinyl coenzyme A and leucine are comparable activators. Thus, the insulinotropic properties of monomethyl succinate could result from it increasing the level of succinyl coenzyme A and decreasing the level of GTP via the succinate thiokinase reaction.     

Intersubstrate competitions and evidence for compartmentation in mitochondria

1. The respiration of rat liver mitochondria was compared with different substrates, and with sucrose and saline media. The maximum rates of oxidation obtainable from glutamate, oxoglutarate, glutamate+malate, or succinate were higher in the saline (120mm)-tris (20mm) media than in sucrose (250mm)-tris (20mm) mixtures, but the rate with beta-hydroxybutyrate was unchanged. Addition of valinomycin to a medium with sucrose and 5mm-potassium chloride led to rates similar to those measured in saline media; beta-hydroxybutyrate oxidation was unaffected. 2. Some pairs of substrates together provided a rate of oxidation greater than the sum of the separate rates. This is accountable if removal of inhibitory products, such as oxaloacetate, compensates for any mutual competition between the substrates. Other pairs showed rates less than the sum of the separate rates, which is accountable by mutual competition. beta-Hydroxybutyrate and other substrates, except succinate, provided strictly additive rates; with succinate there was evidence for competition. In the presence of rotenone, succinate oxidation was slowed down by citrate, oxoglutarate (+arsenite) and by beta-hydroxybutyrate. 3. The accumulation of substrates in the mitochondria was measured as a function of the concentration and in the presence of possible competitors, or with a potassium salt and valinomycin to induce uptake of K(+). The quantities of oxoglutarate, glutamate and pyruvate increased with the mitochondrial K(+), but the quantities of beta-hydroxybutyrate did not. Most substrates competed between themselves, although citrate accumulation was somewhat increased by oxoglutarate. beta-Hydroxybutyrate competed for accumulation only with succinate, and was unaffected by other substrates. beta-Hydroxybutyrate accumulation was almost linearly related to applied concentration (up to 5mm), and its rate of reaction was linearly dependent on concentration up to the highest value tested (0.75mm). Hence it differed from other substrates, which are accumulated and oxidized in a manner that follows a saturation law, with K(m) values about 1-10mm. 4. It is concluded that beta-hydroxybutyrate is stored in a compartment operationally distinct from the space containing K(+) and the NAD-linked substrates. It seems likely that succinate enters both compartments. 5. The degree of accumulation and the effectiveness of an anion as a competitor (as judged by low K(i)) increases with the net charge. This is indicative of an electrostatic interaction with positive sites. It is suggested that the facilitating influence of dicarboxylic acids on the permeation of tricarboxylic acids may be due to the assembling of pairs of the positive carriers by the former, so favouring the chance of there being three or more carriers in a small volume of space near the boundary to interact with the tricarboxylic anion.     

3-Aminopicolinate inhibits phosphoenolpyruvate carboxykinase in hepatocytes and increases release of gluconeogenic precursors from peripheral tissues

3- Aminopicolinate , a hyperglycemic agent that activates purified phosphoenolpyruvate carboxykinase in the presence of Fe2+, inhibits glucose synthesis from lactate, pyruvate, asparagine, monomethyl succinate, or glutamine but does not affect that from fructose, dihydroxyacetone, sorbitol, or glycerol in hepatocytes isolated from rats fasted for 24 h. Lactate production from monomethyl succinate by hepatocytes is also inhibited by 3- aminopicolinate . This compound elevates the concentrations of pyruvate, malate, and aspartate but decreases that of phosphoenolpyruvate in hepatocytes incubated with lactate plus pyruvate. In rats, the ability of 3- aminopicolinate to elevate blood glucose concentration is unimpaired by renalectomy . The drug does not significantly affect glycemia in functionally hepatectomized rats but accelerates blood lactate and pyruvate accumulation to higher maximum concentrations even when kidney function is also ablated. It is concluded that 3- aminopicolinate inhibits phosphoenolpyruvate carboxykinase in hepatocytes, that the reported stimulation of renal glutaminase and glutamine gluconeogenesis by this compound does not contribute significantly to its hyperglycemic property, and that the drug increases gluconeogenic substrate supply from peripheral tissues.     

Effects of carbon–dioxide-bicarbonate mixtures on oxidative phosphorylation by cauliflower mitochondria

1. Carbon dioxide-bicarbonate mixtures markedly inhibited oxidation and phosphorylation rates of mitochondria prepared from cauliflower. Inhibition occurred with succinate, malate, citrate, isocitrate and NADH as substrates. 2. Indophenol-reductase systems with malate, succinate, isocitrate and NADH as substrates were inhibited by 5% and 15% carbon dioxide. Cytochrome c oxidase was not inhibited by 15% carbon dioxide.     

The role of malate in hormone-induced enhancement of mitochondrial respiration

Shortly after the injection of glucagon, epinephrine, norepinephrine, vasopressin, or angiotensin II into fasted rats, mitochondria isolated from their livers contained elevated concentrations of malate and oxidized citrate, alpha-ketoglutarate, and, in some cases, succinate more rapidly than mitochondria from fasted, control rats. The administration of tryptophan, lactate, or ethanol and refeeding of rats fasted 24 h result in similar elevations of mitochondrial malate concentration and oxidation of added substrates. Treatments that resulted in elevated mitochondrial malate resulted also in increased uptake of added citrate, alpha-ketoglutarate, pyruvate, and, in some cases, succinate. It is postulated that the well-documented effect of gluconeogenic hormones on mitochondrial oxidation of carboxylic substrates may be mediated by malate which not only yields oxalacetate to support the tricarboxylic acid cycle but also facilitates the transport of added substrates, and which is regenerated in the tricarboxylic acid cycle.     

Factors limiting respiration by isolated cauliflower mitochondria

Oxygen consumption by isolated cauliflower mitochondria oxidising malate, succinate or NADH was less than when a combination of any two substrates was supplied. The rates obtained with any two were less than the aggregate of the individual rates. Only with the combination of malate plus succinate did the presence of the NADH result in faster rates of oxygen uptake. Conversely, malate and succinate separately, or in combination, inhibited the oxidation of erogenous NADH. The rate-limiting step for the oxidation of these substrates lies within the respiratory chain but on that part used exclusively by each substrate. The addition of NADH with either malate or succinate, or both, saturates the chain and makes the rate limiting step a component common to all pathways. Malate and isocitrate oxidation were considerably greater in disrupted, than in intact mitochondria, eliminating substrate dehydrogenases as rate-limiting factors. Substrate entry was also eliminated in the case of malate oxidation. It is suggested that the tricarboxylate transporter may restrict the rate of isocitrate oxidation.     

Calcium transport in bovine sperm mitochondria: effect of substrates and phosphate.

Calcium uptake into filipin-treated bovine spermatozoa is completely inhibited by the uncoupler CCCP or by ruthenium red. Both Pi and mitochondrial substrates are required to obtain the maximal rate of calcium uptake into the sperm mitochondria. Bicarbonate and other anions such as lactate, acetate or beta-hydroxybutyrate do not support a high rate of calcium uptake. There are significant differences among various mitochondrial substrates in supporting calcium uptake. The best substrates are durohydroquinone, alpha-glycerophosphate and lactate. Pyruvate is a relatively poor substrate, and its rate can be greatly enhanced by malate or succinate but not by oxalacetate or lactate. This stimulation is blocked by the dicarboxylate translocase inhibitor, butylmalonate and can be mimiced by the non-metabolized substrate D-malate. The Ka for pyruvate was found to be 17 microM and 67 microM in the presence and absence of L-malate, respectively. The Ka for L-malate is 0.12 mM. It is suggested that in addition to the known pyruvate/lactate translocase there is a second translocase for pyruvate which is malate/succinate-dependent and does not transport lactate. In the presence of succinate, glutamate stimulates calcium uptake 3-fold, and this effect is not inhibited by rotenone. In the presence of glutamate plus malate or oxalacetate there is only an additive effect. It is suggested that glutamate stimulates succinate transport and/or oxidation in bovine sperm mitochondria. The alpha-hydroxybutyrate is almost as good as lactate in supporting calcium uptake. Since the alpha-keto product is not further metabolized in the citric acid cycle, it is suggested that lactate can supply the mitochondrial needs for NADH from its oxidation to pyruvate by the sperm lactate dehydrogenase x. Thus, when there is sufficient lactate in the sperm mitochondria, pyruvate need not be further metabolized in the citric acid cycle in order to supply more NADH.     

Methoxyacetic acid and ethoxyacetic acid inhibit mitochondrial function in vitro

Ethylene glycol monomethyl ether (EGME) and ethylene glycol monoethyl ether (EGEE) have recently been shown to be potent reproductive toxicants in laboratory animals. The toxicity of these compounds is believed to be due to their metabolites, methoxyacetic acid (MAA) and ethoxyacetic acid (EAA). Since the primary targets of EGME and EGEE appear to be tissues with rapidly dividing cell systems and high rates of respiration and energy metabolism, the effects of these compounds and their proposed metabolites on mitochondria were investigated. At concentrations beginning at 3.85 mM, MAA and EAA inhibited state 3 respiration and the respiratory control ratio (RCR) in hepatic mitochondria with either succinate or citrate/malate as substrates. Cytochrome c oxidase activity was also inhibited by both metabolites at similar concentrations. The effects of MAA, the metabolite from the more potent compound, on testicular mitochondria were found to be comparable. Neither EGME or EGEE appeared to affect mitochondrial function at concentrations as high as 238 or 113 mM, respectively. These results support the hypothesis that the toxicity of EGME and EGEE are due to their metabolites, MAA and EAA, and that these metabolites may exert their effects, in part, on mitochondrial function.     

Properties of Wheat Mitochondria. Study of Substrates, Cofactors and Inhibitors

Isolated mitochondria of wheat shoots oxidize α- ketoglutarate, DL-malate succinate and NADH with good relative respiration control and ADP: O ratio. They have high affinity for α-ketoglutarate and NADH as substrates and utilize malate and succinate with a respiration ratio of about one-half of α-ketoglutarate. The average ADP : O ratios approach the expected theoretical values, i.e., 3.6 ± 0.2 for α-ketoglutarate, 1.8 ± 0.2 for succinate, and 2.8 ± 0.2 for malate. The ADP: O ratio with NADH is 1.8 ± 0.2. The maximum coupling of oxidation and phosphorylation is obtained at concentrations of 10 mM, 2 mM, 10 mM and 8 mM for α-ketoglutarate, NADH, malate and succinate, respectively. — Wheat mitochondria have little or no dependence on added cofactors. Mitochondria prepared by our procedure apparently retain sufficient amounts of endogenous cofactors required for NAD-linked systems. FAD⁺ is found to improve succinate oxidation. Cytochrome c does not have any significant effect on respiratory parameters of wheat mitochondria. — Wheat mitochondria are some -what resistant to DNP at 1.7 × 10^-5M. Malonate seems to improve coupling of α-ketoglutarate oxidation. Other Krebs cycle intermediates have been tested on three major substrates of TCA cycle, i.e., α-ketoglutarate, malate and succinate.     

Metabolite transport across the peribacteroid membrane during broad bean development

A temporal pattern of the peribacteroid membrane (PBM) transport function was studied. Spectrophotometric recording was used for establishing the effect of carbon-and nitrogen-containing substrates (malate, succinate, and glutamate) on the acidification of the peribacteroid space and the intensity of light scattering in the symbiosome suspension from broad bean (Vicia faba L.) root nodules of different age. At the early stages of nodule formation and functioning, PBM is permeable not only for malate and succinate, but also for glutamate, and this permeability fully provides for the active bacteroid division and the nitrogenase complex synthesis in the bacteroids at the expense of the carbon-and nitrogen-containing substrates. Mature nodules are characterized by the greatest nitrogen-fixing activity. In these nodules, PBM is selectively permeable for malate and succinate, but constitutes a barrier for glutamate. Thereby, mutually beneficial relations between the symbiotic partners are achieved. In senescent nodules, a rearrangement of symbiotic interactions is directed toward a minimization of both carbon and nitrogen metabolite consumption by the bacteroids. It is concluded that, in the course of the development of the legume-rhizobia symbiosis, the PBM transport function is changed. This function determines a qualitatively different pattern of symbiotic partner interactions in the following sequence: parasitism-mutualism-commensalism.     

Isolation of dicarboxylic acid- and glucose-binding proteins from Pseudomonas aeruginosa.

Inducible binding proteins for C4-dicarboxylic acids (DBP) and glucose (GBP) were isolated from Pseudomonas aeruginosa by extraction of exponential-phase cells with 0.2 M MgC12 (pH 8.5) and by an osmotic shock procedure without affecting cell viability. DBP synthesis was induced by growth on aspartate, alpha-ketoglutarate, succinate, fumarate, malate, and malonate but not by growth on acetate, citrate, pyruvate, or glucose. Binding of succinate by DBP was competitively inhibited by 10-fold concentrations of fumarate and malate but not by a variety of related substances. GBP synthesis and transport of methyl alpha-glucoside by whole cells were induced by growth on glucose or pyruvate plus galactose, 2-deoxyglucose, or methyl alpha-glucoside but not by growth on gluconate, succinate, acetate, or pyruvate. The binding of radioactive glucose by GBP was significantly inhibited by 10-fold concentrations of glucose, galactose, and glucose-1-phosphate but not by the other carbohydrates tested. The binding of glucose by GBP or succinate by DBP did not result in any chemical alteration of the substrates.     

The magnesium-protoporphyrin IX (oxidative) cyclase system. Studies on the mechanism and specificity of the reaction sequence.

Mg-protoporphyrin IX monomethyl ester cyclase activity was assayed in isolated developing cucumber (Cucumis sativus L. var. Beit Alpha) chloroplasts [Chereskin, Wong & Castelfranco (1982) Plant Physiol. 70, 987-993]. The presence of both 6- and 7-methyl esterase activities was detected, which permitted the use of diester porphyrins in a substrate-specificity study. It was found that: (1) the 6-methyl acrylate derivative of Mg-protoporphyrin monomethyl ester was inactive as a substrate for cyclization; (2) only one of the two enantiomers of 6-beta-hydroxy-Mg-protoporphyrin dimethyl ester had detectable activity as a substrate for the cyclase; (3) the 2-vinyl-4-ethyl-6-beta-oxopropionate derivatives of Mg-protoporphyrin mono- or di-methyl ester were approx. 4 times more active as substrates for cyclization than the corresponding divinyl forms; (4) at the level of Mg-protoporphyrin there was no difference in cyclase activity between the 4-vinyl and 4-ethyl substrates; (5) reduction of the side chain of Mg-protoporphyrin in the 2-position from a vinyl to an ethyl resulted in a partial loss of cyclase activity. This work suggests that the original scheme for cyclization proposed by Granick [(1950) Harvey Lect. 44, 220-245] should now be modified by the omission of the 6-methyl acrylate derivative of Mg-protoporphyrin monomethyl ester and the introduction of stereo-specificity at the level of the hydroxylated intermediate.     

Membrane enzymes associated with the dissimilation of some citric acid cycle substrates and production of extracellular oxidation products in chemostat cultures of Pseudomonas fluorescens

Enzyme activities forming extracellular products from succinate, fumarate, and malate were examined using washed cell suspensions of Pseudomonas fluorescens from chemostat cultures. Membrane-associated enzyme activities (glucose, gluconate, and malate dehydrogenases), producing large accumulations of extracellular oxidation products in carbon-excess environments, have previously been found in P. fluorescens. Investigations carried out here have demonstrated the presence in this microorganism of a malic enzyme activity which produces extracellular pyruvate from malate in carbon-excess environments. Although the three membrane dehydrogenase enzymes decrease significantly in carbon-limited chemostat cultures, malic enzyme activity was found to increase fourfold under these conditions. The regulation of malate dehydrogenase and malic enzyme by malate or succinate was similar. Malate dehydrogenase increased and malic enzyme decreased in carbon-excess cultures. The opposite effect was observed in carbon-limited cultures. When pyruvate or glucose was used as the carbon source, malate dehydrogenase was regulated similarly by the available carbon concentration, but malic enzyme activity producing extracellular pyruvate was not detected. While large accumulations of extracellular oxalacetate and pyruvate were produced in malate-excess cultures, no extracellular oxidation products were detected in succinate-excess cultures. This may be explained by the lack of detectable activity for the conversion of added external succinate to extracellular fumarate and malate in cells from carbon-excess cultures. In cells from carbon-limited (malate or succinate) cultures, very active enzymes for the conversion of succinate to extracellular fumarate and malate were detected. Washed cell suspensions from these carbon-limited cultures rapidly oxidized added succinate to extracellular pyruvate through the sequential action of succinate dehydrogenase, fumarase, and malic enzyme. Succinate dehydrogenase and fumarase activities producing extracellular products were not detected in cells from chemostat cultures using pyruvate or glucose as the carbon source. Uptake activities for succinate, malate, and pyruvate also were found to increase in carbon-limited (malate or succinate) and decrease in carbon-excess cultures. The role of the membrane-associated enzymes forming different pathways for carbon dissimilation in both carbon-limited and carbon-excess environments is discussed.     

ORGANIC MERCURIAL ENCEPHALOPATHY: IN VIVO AND IN VITRO EFFECTS OF METHYL MERCURY ON SYNAPTOSOMAL RESPIRATION

—A reproducible model of subacute methyl mercury (MeHg) intoxication was developed in the adult rat following the daily intragastric administration of 10 mg methyl mercury/kg body wt. Synaptosomes isolated from animals during the latent phase of mercury neurotoxicity (6-10 days) demonstrated no significant change in respiratory control, State 3, State 4, or 2,4-dinitrophenol stimulated respiration with succinate, glutamate or pyruvate plus malate. During the neurotoxic phase, a significant decline in respiratory control was evident with all substrates. Cerebellar synaptosomes revealed qualitatively similar but quantitatively greater inhibition of 2,4-dinitrophenol stimulated respiration during the latent and neurotoxic phases with glutamate. In vitro studies of synaptosome respiration, oxidative phosphorylation and respiratory control with 5-15 μm -methyl mercury revealed a stimulation of initial State 4 respiration, loss of RCI, inhibition of State 3 but no change in the gramicidin or 2,4-dinitrophenol uncoupled rate supported by pyruvate-malate. Phosphate did not relieve the State 3 inhibition. At 25 μm -methyl mercury and above, considerable inhibition of electron transfer occurred. At this concentration, cytochrome c oxidase was inhibited 50%. Isosmotic replacement of medium KC1 by mannitol reduced the MeHg stimulation of State 4 respiration but had no effect on MeHg inhibition of ADP stimulated respiration. Half-maximal stimulation of State 4 respiration by MeHg occurred at [K]⁺⋍ 6 mm . These findings are compatible with an energy-linked methyl mercury induced cation translocation across the synaptosome (mitochondrial) membrane.     

Cloning and functional characterization of a high-affinity Na(+)/dicarboxylate cotransporter from mouse brain

Neurons contain a high-affinity Na(+)/dicarboxylate cotransporter for absorption of neurotransmitter precursor substrates, such as alpha-ketoglutarate and malate, which are subsequently metabolized to replenish pools of neurotransmitters, including glutamate. We have isolated the cDNA coding for a high-affinity Na(+)/dicarboxylate cotransporter from mouse brain, called mNaDC-3. The mRNA coding for mNaDC-3 is found in brain and choroid plexus as well as in kidney and liver. The mNaDC-3 transporter has a broad substrate specificity for dicarboxylates, including succinate, alpha-ketoglutarate, fumarate, malate, and dimethylsuccinate. The transport of citrate is relatively insensitive to pH, but the transport of succinate is inhibited by acidic pH. The Michaelis-Menten constant for succinate in mNaDC-3 is 140 microM in transport assays and 16 microM at -50 mV in two-electrode voltage clamp assays. Transport is dependent on sodium, although lithium can partially substitute for sodium. In conclusion, mNaDC-3 likely codes for the high-affinity Na(+)/dicarboxylate cotransporter in brain, and it has some unusual electrical properties compared with the other members of the family.     

Stimulation by quinones of cyanide-resistant respiration in rat liver and heart mitochondria

It was shown that hydrophilic benzo- and naphthoquinones stimulate the cyanide-resistant respiration in liver and muscle mitochondria when succinate or NADH and glutamate or malate are used as oxidation substrates. The substrate-dependent oxygen uptake in the presence of cyanide is initiated by menadione, vicasol, 1.2-naphthoquinone, coenzyme Q0 and duroquinone. Rotenone and antimycin A do not inhibit the cyanide-resistant respiration. Oxidation of glutamate and malate in the course of CN-resistant respiration is inhibited by ortho- and bathophenanthroline and p-chloromercurybenzoate, whereas succinate oxidation by tenoyltrifluoroacetone, carboxin and pentachlorophenol. Superoxide dismutase, Cu2+ and catalase inhibit the CN-resistant respiration in the presence of quinones. Addition of catalase to the experimental cell causes O2 release.     

Action of diclofenac on kidney mitochondria and cells

The mitochondrial membrane potential measured in isolated rat kidney mitochondria and in digitonin-permeabilized MDCK type II cells pre-energized with succinate, glutamate, and/or malate was reduced by micromolar diclofenac dose-dependently. However, ATP biosynthesis from glutamate/malate was significantly more compromised compared to that from succinate. Inhibition of the malate-aspartate shuttle by diclofenac with a resultant decrease in the ability of mitochondria to generate NAD(P)H was demonstrated. Diclofenac however had no effect on the activities of NADH dehydrogenase, glutamate dehydrogenase, and malate dehydrogenase. In conclusion, decreased NAD(P)H production due to an inhibition of the entry of malate and glutamate via the malate-aspartate shuttle explained the more pronounced decreased rate of ATP biosynthesis from glutamate and malate by diclofenac. This drug, therefore affects the bioavailability of two major respiratory complex I substrates which would normally contribute substantially to supplying the reducing equivalents for mitochondrial electron transport for generation of ATP in the renal cell.