KB-R7943, an inhibitor of the reverse Na+ /Ca2+ exchanger, blocks N-methyl-D-aspartate receptor and inhibits mitochondrial complex I

BACKGROUND AND PURPOSE

An isothiourea derivative (2-[2-[4-(4-nitrobenzyloxy)phenyl]ethyl]isothiourea methane sulfonate (KB-R7943), a widely used inhibitor of the reverse Na⁺/Ca²⁺ exchanger (NCX_rev), was instrumental in establishing the role of NCX_rev in glutamate-induced Ca²⁺ deregulation in neurons. Here, the effects of KB-R7943 on N-methyl-D-aspartate (NMDA) receptors and mitochondrial complex I were tested.

EXPERIMENTAL APPROACH

Fluorescence microscopy, electrophysiological patch-clamp techniques and cellular respirometry with Seahorse XF24 analyzer were used with cultured hippocampal neurons; membrane potential imaging, respirometry and Ca²⁺ flux measurements were made in isolated rat brain mitochondria.

KEY RESULTS

KB-R7943 inhibited NCX_rev with IC₅₀= 5.7 ± 2.1 µM, blocked NMDAR-mediated ion currents, and inhibited NMDA-induced increase in cytosolic Ca²⁺ with IC₅₀= 13.4 ± 3.6 µM but accelerated calcium deregulation and mitochondrial depolarization in glutamate-treated neurons. KB-R7943 depolarized mitochondria in a Ca²⁺-independent manner. Stimulation of NMDA receptors caused NAD(P)H oxidation that was coupled or uncoupled from ATP synthesis depending on the presence of Ca²⁺ in the bath solution. KB-R7943, or rotenone, increased NAD(P)H autofluorescence under resting conditions and suppressed NAD(P)H oxidation following glutamate application. KB-R7943 inhibited 2,4-dinitrophenol-stimulated respiration of cultured neurons with IC₅₀= 11.4 ± 2.4 µM. With isolated brain mitochondria, KB-R7943 inhibited respiration, depolarized organelles and suppressed Ca²⁺ uptake when mitochondria oxidized complex I substrates but was ineffective when mitochondria were supplied with succinate, a complex II substrate.

CONCLUSIONS AND IMPLICATIONS

KB-R7943, in addition to NCX_rev, blocked NMDA receptors in cultured hippocampal neurons and inhibited complex I in the mitochondrial respiratory chain. These findings are critical for the correct interpretation of experimental results obtained with KB-R7943 and a better understanding of its neuroprotective action.     

Identification of subcellular organelles involved in Ba2+- and Cd2+-induced adrenomedullary secretion

To determine which subcellular organelles of bovine adrenal medulla are mainly involved in catecholamine secretion evoked by Ba²⁺ or Cd²⁺, glands were stimulated with these trace metals and subsequently subcellular fractions were assayed for Ba or Cd. Media of varying pH were used since low H+ concentrations are thought to promote Ba²⁺ and Cd²⁺ penetration into adrenal medulla. Of all the adrenomedullary fractions isolated, only the microsomes contained significantly more Cd when exposure to Cd²⁺ was accomplished at the high pH, and only mitochondrial Ba was enhanced after exposure to Ba²⁺ at the high pH. Furthermore, a significant correlation was found between adrenal catecholamine release and residual microsomal Cd. Similary, adrenal catecholamine release by Ba²⁺ was proportional to the Ba content of mitochondria. Since Cd and Ba levels in tissue fractions were determined only after a 15-min washout of the adrenals with trace metal-free Locke's solution, residual Cd and Ba in microsomes and mitochondria, respectively, probably represent metallic cations removed from the cytoplasm during termination of the secretory response. It is therefore proposed that microsomal structures remove Cd²⁺ from the cytoplasm to limit Cd²⁺-induced adrenal catecholamine release and that mitochondria remove Ba²⁺ from adrenomedullary cytoplasm to terminate Ba²⁺-induced catecholamine release.     

Effects of quinidine and propranolol on energy transduction in beef heart mitochondria.

The effects of quinidine and propranolol on mitochondrial respiration and on three respiration-dependent functions (oxidative phosphorylation, calcium uptake, and uncoupler-stimulated respiration) were studied. Both quinidine and propranolol inhibited respiration and three respiration-dependent functions in the presence of pyruvate plus malate or succinate plus rotenone as the substrates. Furthermore, both quinidine and propranolol inhibited ATP-P_i exchange, a mitochondrial energy-coupling reaction that does not involve respiration. Inhibition by propranolol but not by quinidine was strongly depended on the KCl concentration of the medium, the inhibition being maximal at low concentrations. The effect of KCl appears to lower the affinity of propranolol to the mitochondrial membrane.     

2,5,2',5'-Tetrachlorobiphenyl impairs the bioenergetic functions of isolated rat liver mitochondria

The effects of 2,5,2',5'-tetrachlorobiphenyl (25TCB) on parameters related to the bioenergetic functions of isolated rat liver mitochondria were investigated. State 3 respiration was inhibited by 25TCB with both succinate and glutamate/malate as the respiratory substrates. The extent of inhibition with succinate was larger than that observed with glutamate/malate. The concentration of 25TCB required to cause 50% inhibition for succinate was 51 microM, but with glutamate/malate, only 53% inhibition was observed at 200 microM. 25TCB stimulated state 4 respiration after 1-2 min lag period; state 4 respiration in the presence of glutamate/malate was more intensely stimulated by 25TCB than in the presence of succinate. 25TCB dissipated the membrane potential across the mitochondrial membranes. Isolated rat liver mitochondria accumulate large amounts of Ca2+ at the expense of respiration-linked energy (substrate oxidation) or of that provided by the hydrolysis of ATP by the mitochondrial ATPase. The Ca2+ accumulation by mitochondria was severely depressed by 25TCB when the energy was supplied by respiration. Furthermore, the inhibition of Ca2+ accumulation by 25TCB with succinate was greater than that produced with glutamate/malate. On the other hand, with ATP as the source of energy, 25TCB inhibited Ca2+ accumulation at high concentrations. 25TCB also released Ca2+ from mitochondria that had already accumulated Ca2+, indicating that mitochondrial membrane integrity was damaged by the intercalation of 25TCB. These results show that 25TCB impairs mitochondrial energy production, and inhibits Ca2+ sequestration by mitochondria.     

Effects of cinnabarinic acid on mitochondrial respiration.

The effects of cinnabarinic acid on the respiration of rat liver and beef heart mitochondria in the presence of various substrates were studied. Cinnabarinic acid inhibits respiration of rat liver mitochondria with α-ketoglutarate, malate, isocitrate, pyruvate and glutamate. Oxidation of succinate and β-hydroxybutyrate is not or only slightly inhibited. α-Ketoglutarate oxidation is most sensitive towards cinnabarinic acid followed by pyruvate, glutamate, malate and isocitrate oxidation. Respiration of beef heart mitoehondria is inhibited in the presence of α-ketoglutarate, glutamate, β-hydroxybutyrate and malate. Cinnabarinic acid also activates the adenosine triphosphatase of intact rat liver mitochondria. Mitochondrial respiration inhibited either by rotenone, amytal or antimycin in the presence of β-hydroxybutrate or glutamate is restored by the addition of cinnabarinic acid. This cinnabarinic acidmediated respiration is sensitive to dicumarol and cyanide. Oxidation of α-ketoglutarate blocked by these inhibitors and oxidation of succinate inhibited by antimycin is not restored. The cinnabarinic acid mediated respiration shows some degree of respiratory control. $\text{P}\text{O}$ ratios of 0–75 were observed. It is concluded that reducing equivalents are transferred from NADH upon the interaction of menadione reductase to cinnabarinie acid and enter the respiratory chain at the level of cytochrome cc₁.     

EGCG inhibits Cd2+-induced apoptosis through scavenging ROS rather than chelating Cd2+ in HL-7702 cells

Context and objective: Epigallocatechin-3-gallat (EGCG), the major catechin in green tea, shows a potential protective effect against heavy metal toxicity to humans. Apoptosis is one of the key events in cadmium (Cd²⁺)-induced cytotoxicity. Nevertheless, the study of EGCG on Cd²⁺-induced apoptosis is rarely reported. The objective of this study was to clarify the effect and detailed mechanism of EGCG on Cd²⁺-induced apoptosis.

Methods: Normal human liver cells (HL-7702) were treated with Cd²⁺ for 21?h, and then co-treated with EGCG for 3?h. Cell viability, apoptosis, intracellular reactive oxygen species (ROS), malondialdehyde (MDA), mitochondrial membrane potential (MMP) and caspase-3 activity were detected. On the other hand, the chelation of Cd²⁺ with EGCG was tested by UV-Vis spectroscopy analysis and Nuclear Magnetic Resonance (¹H NMR) spectroscopy under neutral condition (pH 7.2).

Results and conclusion: Cd²⁺ significantly decreased the cell viability and induced apoptosis in HL-7702 cells. Conversely, EGCG co-treatment resulted in significant inhibition of Cd²⁺-induced reduction of cell viability and apoptosis, implying a rescue effect of EGCG against Cd²⁺ poisoning. The protective effect most likely arises from scavenging ROS and maintaining redox homeostasis, as the generation of intracellular ROS and MDA is significantly reduced by EGCG, which further prevents MMP collapse and suppresses caspase-3 activity. However, no evidence is observed for the chelation of EGCG with Cd²⁺ under neutral condition. Therefore, a clear conclusion from this work can be made that EGCG could inhibit Cd²⁺-induced apoptosis by acting as a ROS scavenger rather than a metal chelating agent.     

Protective effects of verapamil and diltiazem against inorganic phosphate induced impairment of oxidative phosphorylation of isolated heart mitochondria

The effects of verapamil and diltiazem on oxidative phosphorylation of isolated rabbit heart mitochondria were related to the experimental conditions employed. In an assay medium containing 250 mM sucrose, 1 mM pyruvate and 5 mM potassium phosphate buffer (pH 7) at 37° (sucrose medium), only a high concentration of verapamil (200–800 μM) or diltiazem (400–600 μM) affected mitochondria. State 4 respiration was stimulated, state 3 respiration was inhibited, and the ADP: O ratio was decreased by these drugs in sucrose medium. These effects resulted in a depression of the respiratory control index (RCI) and oxidative phosphorylation rate (OPR). On the other hand, in an assay medium containing 150 mM KCl, 1 mM pyruvate and 2 mM potassium phosphate buffer (pH 7) at 37° (KCl medium), the high rate of state 3 respiration and the normal value of the ADP: O ratio were not influenced significantly by diltiazem (400–800 μM) or verapamil (200–400 μM). These data indicate that neither verapamil nor diltiazem has an effect on the normal, functioning, isolated mitochondria in KCl medium. Elevation of inorganic phosphate (P₁) from 2 to 5 mM in the KCl medium induced a swelling of the mitochondria, inhibition of state 3 respiration, and a decrease in the ADP: O ratio, RCI and OPR. Under these conditions, a low concentration of verapamil (25–200 μM) or diltiazem (50–800 μM) inhibited the swelling effect of P_i and at the same time prevented the P_i-induced decrease in state 3 respiration, and the ADP: O ratio, RCI and OPR. In a medium containing 150 mM KCl, 1 mM pyruvate, 2 mM ADP and 10 μM palmitoyl-CoA, the addition of 5 mM P_i induced swelling of mitochondria and a decreased rate of state 3 respiration. Under these conditions, even a low concentration of verapamil (6–200 μM) or diltiazem (25–400 μM) inhibited swelling and prevented the inhibition of state 3 respiration. It is concluded that low concentrations of verapamil and diltiazem had no effect on unswollen heart mitochondria. An increase in the free P_i concentration induced swelling of mitochondria and resulted in an inhibition of oxidative phosphorylation, provided that the extramitochondrial potassium concentration was as high as that normally found in the cytosol. Under these conditions, a low concentration of verapamil and diltiazem was able to affect the mitochondrial membranes so as to prevent P_i-induced swelling and the related inhibition of oxidative phosphorylation.     

Effects of cresols (o-, m-, and p-isomers) on the bioenergetic system in isolated rat liver mitochondria

It is known that o-, m- and p-cresols exert a toxic effect on rat liver cells. However, there is little information on the mechanism for the hepatotoxicity of cresols. We, therefore, investigated the effects of o-, m-, and p-cresols on the bioenergetic system using isolated rat liver mitochondria. When o-, m- or p-cresol was added to liver mitochondria with glutamate or succinate at concentrations of 0.3 to 6.0 mumol/mg protein, each cresol isomer reduced the rate of state 3 respiration dose-dependently. Three cresol isomers at 6.0 mumol/mg protein each inhibited state 3 respiration in liver mitochondria with glutamate or succinate by about 60 or 20%, respectively. The three isomers affected NAD- and succinate-linked respirations in liver mitochondria, by which the respiratory control ratio was dose-dependently attenuated. The inhibitory effects of o-, m- and p-cresols on the NAD-linked respiration were stronger than those on the succinate-linked respiration. However, three cresol isomers had little effect on the P/O ratio in liver mitochondria with glutamate or succinate. Three cresol isomers at 15 mumol/mg protein each induced the swelling in the absence of Ca2+ in medium and accelerated the swelling of liver mitochondria in the presence of Ca2+ in medium. These results indicate that o-, m- and p-cresols inhibit liver mitochondrial respiration and induce or accelerate the swelling of liver mitochondria, and suggest that liver mitochondria may be one of the targets for the hepatotoxic actions of cresols.     

To involvement the conformation of the adenine nucleotide translocase in opening the Tl+-induced permeability transition pore in Ca2+-loaded rat liver mitochondria

The conformation of adenine nucleotide translocase (ANT) has a profound impact in opening the mitochondrial permeability transition pore (MPTP) in the inner membrane. Fixing the ANT in ‘c’ conformation by phenylarsine oxide (PAO), tert-butylhydroperoxide (tBHP), and carboxyatractyloside as well as the interaction of 4,4′-diisothiocyanostilbene-2,2′-disulfonate (DIDS) with mitochondrial thiols markedly attenuated the ability of ADP to inhibit the MPTP opening. We earlier found (Korotkov and Saris, 2011) that calcium load of rat liver mitochondria in medium containing TlNO₃ and KNO₃ stimulated the Tl⁺-induced MPTP opening in the inner mitochondrial membrane. The MPTP opening as well as followed increase in swelling, a drop in membrane potential (ΔΨ_mito), and a decrease in state 3, state 4, and 2,4-dinitrophenol-uncoupled respiration were visibly enhanced in the presence of PAO, tBHP, DIDS, and carboxyatractyloside. However, these effects were markedly inhibited by ADP and membrane-penetrant hydrophobic thiol reagent, N-ethylmaleimide (NEM) which fix the ANT in ‘m’ conformation. Cyclosporine A additionally potentiated these effects of ADP and NEM. Our data suggest that conformational changes of the ANT may be directly involved in the opening of the Tl⁺-induced MPTP in the inner membrane of Ca²⁺-loaded rat liver mitochondria. Using the Tl⁺-induced MPTP model is discussed in terms finding new transition pore inhibitors and inducers among different chemical and natural compounds.     

Antidiabetic sulphonylureas activate mitochondrial permeability transition in rat skeletal muscle

Antidiabetic sulphonylureas can bind to various intracellular organelles including mitochondria. The aim of this study was to monitor the influence of antidiabetic sulphonylureas on membrane permeability in mitochondria isolated from rat skeletal muscle. The effects of glibenclamide (and other sulphonylurea derivatives) on mitochondrial function were studied by measuring mitochondrial swelling, mitochondrial membrane potential, respiration rate and Ca2+ transport into mitochondria. We observed that glibenclamide induced mitochondrial swelling (EC50 = 8.2 +/- 2.5 microM), decreased the mitochondrial membrane potential and evoked Ca2+ efflux from the mitochondrial matrix. These effects were blocked by 2 microM cyclosporin A, an inhibitor of the mitochondrial permeability transition. Moreover, 30 microM glibenclamide accelerated the respiratory rate in the presence of glutamate/malate, substrates of complex I of the mitochondrial respiratory chain. In conclusion, we postulate that the antidiabetic sulphonylureas activate the mitochondrial permeability transition in skeletal muscle by increasing its sensitivity to Ca2+.     

Diazinon impairs bioenergetics and induces membrane permeability transition on mitochondria isolated from rat liver

ABSTRACT

Diazinon (DZN) is a broad-spectrum insecticide extensively used to control pests in crops and animals. Several investigators demonstrated that DZN produced tissue toxicity especially to the liver. In addition, the mitochondrion was implicated in DZN-induced toxicity, but the precise role of this organelle remains to be determined. The aim of this study was thus to examine the effects of DZN (50 to 150 μM) on the bioenergetics and mitochondrial permeability transition (MPT) associated processes in isolated rat liver mitochondria. DZN inhibited state-3 respiration in mitochondria energized with glutamate plus malate, substrates of complex I, and succinate, substrate of complex II of the respiratory chain and decreased the mitochondrial membrane potential resulting in inhibition of ATP synthesis. MPT was estimated by the extent of mitochondrial swelling, in the presence of 10 µM Ca²⁺. DZN elicited MPT in a concentration-dependent manner, via a mechanism sensitive to cyclosporine A, EGTA, ruthenium red and N-ethylmaleimide, which was associated with mitochondrial Ca²⁺ efflux and cytochrome c release. DZN did not result in hydrogen peroxide accumulation or glutathione oxidation, but this insecticide oxidized endogenous NAD(P)H and protein thiol groups. Data suggest the involvement of mitochondria, via apoptosis, in the hepatic cytotoxicity attributed to DZN.     

Menadione (2-methyl-1,4-naphthoquinone)-induced Ca2+ release from rat-liver mitochondria is caused by NAD(P)H oxidation

Incubation of rat-liver mitochondria with menadione in the presence of succinate and rotenone resulted in rapid glutathione and NAD(P)H oxidation followed by Ca2+ release and mitochondrial swelling. Ca2+ release, NAD(P)H oxidation and mitochondrial swelling, were also observed in mitochondria from selenium-deficient rats. Glutathione was only slowly oxidized, suggesting that glutathione oxidation, and subsequent NAD(P)H oxidation via the glutathione peroxidase-glutathione reductase system were not required for Ca2+ release by menadione. Isocitrate prevented and reversed Ca2+ release dose-dependently but dicoumarol had no effect indicating that NADH-ubiquinone oxidoreductase and not DT-diaphorase was responsible for NAD(P)H oxidation. Superoxide anion radical was formed by cyanide-resistant respiration, suggesting that menadione undergoes a one-electron reduction to an autoxidizable semiquinone radical by NADH-ubiquinone oxidoreductase. The inability of menadione to oxidize glutathione in selenium-deficient mitochondria indicates that the metabolism of the superoxide dismutation product, H2O2, by glutathione peroxidase was probably responsible for the glutathione oxidation in selenium-replete mitochondria.     

Effects of Cd on AMPA receptor-mediated synaptic transmission in rat hippocampal CA1 area

Cadmium (Cd²⁺) is a common pollutant that causes a wide variety of toxic effects on the central nervous system. However, the mechanism of Cd²⁺ neurotoxicity remains to be elucidated. In the present study, we examined the effects of Cd²⁺ on AMPA receptor-mediated synaptic transmission and short-term synaptic plasticity in hippocampal CA1 area, using whole-cell patch clamp technique. Cd²⁺ significantly inhibited the peak amplitude of evoked EPSCs (eEPSCs) in a concentration-dependent manner and enhanced the short-term synaptic plasticity including paired-pulse facilitation and frequency facilitation. Cd²⁺ also decreased the frequency and amplitude of spontaneous EPSCs (sEPSCs) but had no effect on those of miniature EPSCs (mEPSCs). These effects of Cd²⁺ may involve a presynaptic mechanism of blockade of action potential-sensitive, calcium-dependent release of glutamate. In addition, Cd²⁺ prolonged the decay time of both sEPSCs and mEPSCs, which suggested a postsynaptic action site of Cd²⁺. This study demonstrates that Cd²⁺ impairs the Schaffer collateral-commissural-CA1 glutamatergic synaptic transmission and short-term plasticity in rat hippocampal slices, which may be a possible contributing mechanism for the Cd²⁺-induced neurotoxic effects.     

Mn2+ sequestration by mitochondria and inhibition of oxidative phosphorylation.

Manganese is known to accumulate in mitochondria and in mitochondria-rich tissues in vivo. Although Ca2+ enhances mitochondrial Mn2+ uptake, ATP-bound Mn2+ is not sequestered by suspended rat brain mitochondria, and ATP binds Mn2+ even more tightly than it binds Mg2+. Physiological levels of the polyamine spermine enhanced 54 Mn2+ uptake at the low [Ca2+]s characteristic of unstimulated cells (approximately 100 nM). With succinate as substrate, Mn2+ inhibited oxygen consumption by suspensions of rat liver mitochondria after the addition of ADP but not after the addition of uncoupler. With glutamate/malate as substrate, Mn2+ inhibited ADP-stimulated respiration and also slightly inhibited uncoupler-stimulated respiration. State 4 (resting) respiration was unchanged in all cases, indicating that the inner membrane retained its impermeability to protons. These results suggest that Mn2+ was not oxidized and that it can interfere directly with oxidative phosphorylation, most likely by binding to the F1 ATPase. Mn2+ may also bind to the NADH dehydrogenase complex, but not strongly enough to affect electron transport in vivo. It is suggested that accumulation of manganese within the mitochondria of globus pallidus may help explain the distinctive pathology of manganism.     

Suramin inhibits respiration and induces membrane permeability transition in isolated rat liver mitochondria.

Suramin, a polysulfonated naphthylamine, caused a dose dependent inhibition of carbonyl cyanide p-(tri-fluoromethoxy)phenylhydrazone-stimulated respiration supported either by succinate or a cocktail of alphaketoglutarate, malate and isocitrate in isolated rat liver mitochondria. The half-maximum effect was obtained at 40 and 140 microM suramin for NADH- or FADH(2)-linked substrates, respectively. The respiration supported by N,N,N'N'-tetramethyl-p-phenylenediamine oxidation was unaffected by suramin (相似文献   

The role of mitochondria and biotransformation in abamectin-induced cytotoxicity in isolated rat hepatocytes

Abamectin (ABA), which belongs to the family of avermectins, is used as a parasiticide; however, ABA poisoning can impair liver function. In a previous study using isolated rat liver mitochondria, we observed that ABA inhibited the activity of adenine nucleotide translocator and F_oF₁-ATPase. The aim of this study was to characterize the mechanism of ABA toxicity in isolated rat hepatocytes and to evaluate whether this effect is dependent on its metabolism. The toxicity of ABA was assessed by monitoring oxygen consumption and mitochondrial membrane potential, intracellular ATP concentration, cell viability, intracellular Ca²⁺ homeostasis, release of cytochrome c, caspase 3 activity and necrotic cell death. ABA reduces cellular respiration in cells energized with glutamate and malate or succinate. The hepatocytes that were previously incubated with proadifen, a cytochrome P450 inhibitor, are more sensitive to the compound as observed by a rapid decrease in the mitochondrial membrane potential accompanied by reductions in ATP concentration and cell viability and a disruption of intracellular Ca²⁺ homeostasis followed by necrosis. Our results indicate that ABA biotransformation reduces its toxicity, and its toxic action is related to the inhibition of mitochondrial activity, which leads to decreased synthesis of ATP followed by cell death.     

An analysis of the effects of Mn on oxidative phosphorylation in liver, brain, and heart mitochondria using state 3 oxidation rate assays

Manganese (Mn) toxicity is partially mediated by reduced ATP production. We have used oxidation rate assays—a measure of ATP production—under rapid phosphorylation conditions to explore sites of Mn²⁺ inhibition of ATP production in isolated liver, brain, and heart mitochondria. This approach has several advantages. First, the target tissue for Mn toxicity in the basal ganglia is energetically active and should be studied under rapid phosphorylation conditions. Second, Mn may inhibit metabolic steps which do not affect ATP production rate. This approach allows identification of inhibitions that decrease this rate. Third, mitochondria from different tissues contain different amounts of the components of the metabolic pathways potentially resulting in different patterns of ATP inhibition. Our results indicate that Mn²⁺ inhibits ATP production with very different patterns in liver, brain, and heart mitochondria. The primary Mn²⁺ inhibition site in liver and heart mitochondria, but not in brain mitochondria, is the F₁F₀ ATP synthase. In mitochondria fueled by either succinate or glutamate + malate, ATP production is much more strongly inhibited in brain than in liver or heart mitochondria; moreover, Mn²⁺ inhibits two independent sites in brain mitochondria. The primary site of Mn-induced inhibition of ATP production in brain mitochondria when succinate is substrate is either fumarase or complex II, while the likely site of the primary inhibition when glutamate plus malate are the substrates is either the glutamate/aspartate exchanger or aspartate aminotransferase.     

Calcium oxalate monohydrate, a metabolite of ethylene glycol, is toxic for rat renal mitochondrial function.

Ethylene glycol poisoning can produce acute renal failure, requiring long-term hemodialysis to restore function. The mechanism of the renal failure is unknown, but is associated with tubular cell necrosis and ethylene glycol metabolism. The end metabolite of ethylene glycol is oxalic acid, the precipitation of which as calcium oxalate monohydrate (COM) crystals in the tubular lumen has been linked with the renal toxicity. Our recent studies suggest that COM is an intracellular toxicant to normal human proximal tubule cells in culture. The present studies were designed to assess whether COM or ionic oxalate alters mitochondrial function so as to lead to renal cell death. In isolated rat kidney mitochondria, COM produced a dose-dependent decrease in State 3 respiration (40% decrease at 0.05 mM COM with either succinate or glutamate/malate as substrate), without affecting either State 4 respiration or the ADP/O ratio. COM, from 0.01-0.05 mM also dose-dependently increased mitochondrial swelling, which was completely blocked by cyclosporin A. The inhibition of State 3 respiration, however, was not reversed by cyclosporin A administration. Potassium oxalate, at concentrations up to 5 mM did not inhibit mitochondrial respiration or induce swelling. These results suggest that COM, and not the oxalate ion, damages rat kidney mitochondria and induces the mitochondrial permeability transition, which may then lead to renal cell death. Since COM is transported intracellularly by kidney cells, the renal toxicity of ethylene glycol may result from inhibition of mitochondrial respiratory function in proximal tubular cells by COM crystals.     

Effects of phenoperidine on rat liver mitochondrial respiration.

Phenoperidine decreases rat liver mitochondrial oxidation of the following substrates in state 3: glutamate, pyruvate/malate mixture, and succinate. The intensity of inhibition is dose-dependent and substrate-dependent. With glutamate which acts at the first phosphorylation site on the respiratory chain, phenoperidine seems to have two effects on mitochondrial oxidative processes: without preincubation, phenoperidine antagonizes mitochondrial oxidation of glutamate presumably by inhibiting enzymes involved in glutamate metabolism such as glutamate dehydrogenase and glutamate oxaloacetate transaminase. Upon a three min preincubation, an additional inhibitory mechanism develops: phenoperidine prevents glutamate from penetrating into the mitochondria. Inhibition without preincubation appears to be non competitive (K_i = 7.5 × 10^?5 M) and it is assumed that it takes place at a site before the 2,4-dinitrophenol (DNP)-sensitive site on the energy transfer process. In state 4, phenoperidine increases the oxidation of these substrates. It decreases the P/O ratio: thus it acts as an uncoupler, although not as potent as DNP. When compared with phenoperidine, levorphanol and pentazocine act as uncouplers but not as energy-transfer inhibitors. DALA-enkephalinamide increases state 4 respiration on glutamate. As for morphine, etorphine, meperidine and fentanyl, they do not act on mitochondrial processes. The effects of opiates on mitochondrial respiration are irrelevant to their morphinomimetic actions because they are not antagonized by naloxone.     

Rapanone,a naturally occurring benzoquinone,inhibits mitochondrial respiration and induces HepG2 cell death

Rapanone is a natural occurring benzoquinone with several biological effects including unclear cytotoxic mechanisms. Here we addressed if mitochondria are involved in the cytotoxicity of rapanone towards cancer cells by employing hepatic carcinoma (HepG2) cells and isolated rat liver mitochondria. In the HepG2, rapanone (20–40 μM) induced a concentration-dependent mitochondrial membrane potential dissipation, ATP depletion, hydrogen peroxide generation and, phosphatidyl serine externalization; the latter being indicative of apoptosis induction. Rapanone toxicity towards primary rats hepatocytes (IC₅₀ = 35.58 ± 1.50 μM) was lower than that found for HepG2 cells (IC₅₀ = 27.89 ± 0.75 μM). Loading of isolated mitochondria with rapanone (5–20 μM) caused a concentration-dependent inhibition of phosphorylating and uncoupled respirations supported by complex I (glutamate and malate) or the complex II (succinate) substrates, being the latter eliminated by complex IV substrate (TMPD/ascorbate). Rapanone also dissipated mitochondrial membrane potential, depleted ATP content, released Ca²⁺ from Ca²⁺-loaded mitochondria, increased ROS generation, cytochrome c release and membrane fluidity. Further analysis demonstrated that rapanone prevented the cytochrome c reduction in the presence of decylbenzilquinol, identifying complex III as the site of its inhibitory action. Computational docking results of rapanone to cytochrome bc1 (Cyt bc1) complex from the human sources found spontaneous thermodynamic processes for the quinone-Q_o and Q_i binding interactions, supporting the experimental in vitro assays. Collectively, these observations suggest that rapanone impairs mitochondrial respiration by inhibiting electron transport chain at Complex III and promotes mitochondrial dysfunction. This property is potentially involved in rapanone toxicity on cancer cells.