Protective role of chlorpromazine on lead-induced damage to heart mitochondria.

1. The protective effect of chlorpromazine (CPZ) on the toxic effects of lead in mitochondrial functions was studied. 2. The findings indicate that CPZ at a concentration of 50 microM protects heart mitochondria against lead-induced Ca2+ uptake inhibition. 3. In addition, CPZ inhibits the drop of the transmembrane potential, as well as mitochondrial swelling as induced by 10 microM Pb2+. 4. It is proposed that the protective effect of chlorpromazine can be due to its stabilizing action on biological membranes.     

The effects of sphingosine on sarcoplasmic reticulum membrane calcium release.

In this study, we report that sphingosine is a potent inhibitor of sarcoplasmic reticulum (SR) calcium release. Evidence is presented demonstrating a direct effect of sphingosine on the SR ryanodine receptor. Calcium release from "skinned" rabbit skeletal muscle fibers and isolated junctional SR derived from the terminal cisternae (TC) was measured in response to caffeine, doxorubicin, 5'-adenylyl-beta,gamma-imidodiphosphate or calcium. Sphingosine inhibited caffeine-induced release in a dose-dependent manner with an IC50 of 0.1 microM for the single muscle fibers and 0.5 microM for the isolated TC vesicles. Near complete blockage of TC calcium release rate was observed with 3 microM sphingosine. Neither sphingomyelin nor sphingosylphosphorylcholine had any effect at the 3 microM level, suggesting that the sphingosine effect was specific. Doxorubicin-induced calcium release and spontaneous calcium release were also blocked by sphingosine. Sphingosine was also capable of stimulating calcium transport in the isolated TC vesicles without an effect on Ca-ATPase activity. Ruthenium red was not capable of substantial additional stimulation of calcium transport nor inhibition of calcium release beyond the action of sphingosine. Sphingosine's blockage of calcium release was not reversed by the protein kinase inhibitor, 1-(5-isoquinolinesulfonyl)-2- methylpiperazine dihydrochloride, suggesting that the action of sphingosine on calcium release was not dependent on ryanodine receptor phosphorylation. Sphingosine significantly increased (8-fold) the Kd for specific [3H]ryanodine binding to TC membranes and decreased the Bmax with a dose dependence similar to the inhibition of calcium release, but sphingosine did not affect the pCa tension relationship of skinned skeletal muscle fibers. These data are consistent with a direct effect of submicromolar sphingosine on the ryanodine receptor. Substantially higher concentrations of sphingosine (30-50 microM) or sphingosylphosphorylcholine (10-20 microM) were capable of inducing calcium release by themselves. Preliminary data indicate that the transverse tubule and not the SR contain substantial sphingomyelinase activity consistent with a transverse tubule source of sphingosine production. Considering that sphingosine is found in micromolar concentrations in some cells, our data indicate that sphingosine generated by the transverse tubule membranes may be a physiologically relevant mechanism for modulating SR calcium release.     

Studies of Ca2+ -dependent smooth muscle mitochondria swelling using flow cytometry and spermine effects on this process

In the experiments, which were carried out using flow cytometry on isolated uterus mitochondria of nonpregnant rats, conditions for studying Ca2+-induced increase in nonspecific permeability of mitochondial membrane were tested. Fluorescent probe nonyl acridin orange was used to determine the purity of isolated mitochondria. Mitochondrial swelling induced by addition of Ca2+ or alamethicin was detected as a decrease in light side scattering (SS). It was shown that mitochondrial swelling in the presence of 100 microM Ca plus 1 microM A23187 was 86 +/- 4% compared with maximal response after alamethicin treatment. The calcium-induced swelling of mitochondria was inhibited by the addition of 5 microM cyclosporin plus 40 microM ADP. Mitochondrial swelling was inhibited by spermine at a dose of 0.1 micromol/mg or induced at a dose of 10 micromol/mg. It was supposed that the experimental approach proposed in this paper can be useful for mitochondrial pore modulating effectors screening.     

Mitochondrial functions during experimentally induced cardiac hypertrophy

When the hearts of albino rats are subjected to pressure-induced stress through constriction of ascending aorta, changes in the mitochondrial functions are observed as early as 24 h after the imposition of the stress. These include the abolition of oxidative phosphorylation, decrease in the energy dependent [⁴⁵Ca]-uptake and decrease in the rate of energized swelling. A large influx of calcium ions and an increase in the fluidity of mitochondrial membranes also occur in this period. At later stages of hypertrophy (17, 28, 40%), these mitochondrial functions gradually return to normal levels.     

Membrane instability in respiring mitochondria: role of phosphate.

Metabolically-induced (spontaneous) high amplitude swelling of mitochondria has been shown to be due to a serial disruption of the mitochondrial membranes [D. Sambasivarao & V. Sitaramam (1985), Biochim Biophys Acta, 806, 195-209]. Phosphate- and arsenate-induced swelling was investigated in mitochondria to evaluate the role of phosphate transport in the instability created in the mitochondrial membranes. Phosphate-induced swelling in respiring mitochondria was similar to spontaneous swelling. Both represent essentially colloidal swelling due to the variable porosity induced in the inner membrane to polyols by respiration. Swelling of non-respiring mitochondria at high ammonium phosphate concentrations was, on the other hand, primarily due to high permeability to phosphate. This membrane instability created by phosphate transport in the surrounding lipid involves neither the endogenous nor the exogenous Ca2+.     

Ethanol withdrawal provokes mitochondrial injury in an estrogen preventable manner

We investigated whether ethanol withdrawal (EW) oxidizes mitochondrial proteins and provokes mitochondrial membrane swelling and whether estrogen deprivation contributes to this problem. Ovariectomized female rats with or without 17β-estradiol (E2)-implantation received a control diet or a liquid ethanol diet (6.5%) for 5 weeks and were sacrificed during EW. Protein oxidation was assessed by measuring carbonyl contents and was visualized by immunochemistry. Mitochondrial membrane swelling as an indicator of mitochondrial membrane fragility was assessed by monitoring absorbance at 540 nm and was compared with that of male rats. Compared to the control diet group and ovariectomized rats with E2-implantation, ovariectomized rats without E2-implantation showed higher carbonylation of mitochondrial proteins and more rapid mitochondrial membrane swelling during EW. Such rapid mitochondrial membrane swelling was comparable to that of male rats undergoing EW. These findings demonstrate that EW provokes oxidative injury to mitochondrial membranes in a manner that is exacerbated by estrogen deprivation.     

Regulation of the mitochondrial matrix volume in vivo and in vitro. The role of calcium.

The ability of alpha-adrenergic agonists and vasopressin to increase the mitochondrial volume in hepatocytes is dependent on the presence of extracellular Ca2+. Addition of Ca2+ to hormone-treated cells incubated in the absence of Ca2+ initiates mitochondrial swelling. In the presence of extracellular Ca2+, A23187 (7.5 microM) induces mitochondrial swelling and stimulates gluconeogenesis from L-lactate. Isolated liver mitochondria incubated in KCl medium in the presence of 2.5 mM-phosphate undergo energy-dependent swelling, which is associated with electrogenic K+ uptake and reaches an equilibrium when the volume has increased to about 1.3-1.5 microliter/mg of protein. This K+-dependent swelling is stimulated by the presence of 0.3-1.0 microM-Ca2+, leading to an increase in matrix volume at equilibrium that is dependent on [Ca2+]. Ca2+-activated K+-dependent swelling requires phosphate and shows a strong preference for K+ over Na+, Li+ or choline. It is not associated with either uncoupling of mitochondria or any non-specific permeability changes and cannot be produced by Ba2+, Mn2+ or Sr2+. Ca2+-activated K+-dependent swelling is not prevented by any known inhibitors of plasma-membrane ion-transport systems, nor by inhibitors of mitochondrial phospholipase A2. Swelling is inhibited by 65% and 35% by 1 mM-ATP and 100 microM-quinine respectively. The effect of Ca2+ is blocked by Ruthenium Red (5 micrograms/ml) at low [Ca2+]. Spermine (0.25 mM) enhanced the swelling seen on addition of Ca2+, correlating with its ability to increase Ca2+ uptake into the mitochondria as measured by using Arsenazo-III. Mitochondria derived from rats treated with glucagon showed less swelling than did control mitochondria. In the presence of Ruthenium Red and higher [Ca2+], the mitochondria from hormone-treated animals showed greater swelling than did control mitochondria. These data imply that an increase in intramitochondrial [Ca2+] can increase the electrogenic flux of K+ into mitochondria by an unknown mechanism and thereby cause swelling. It is proposed that this is the mechanism by which alpha-agonists and vasopressin cause an increase in mitochondrial volume in situ.     

Derivatives of 1,4-dihydropyridines as modulators of ascorbate-induced lipid peroxidation and high-amplitude swelling of mitochondria, caused by ascorbate, sodium linoleate and sodium pyrophosphate

A group of 26 2,6-dimethyl-3,5-disubstituted and 2,6-dimethyl-3,4, 5-trisubstituted-1,4-dihydropyridines (1,4-H(2)Py=1,4-DHPs) and five related pyridines were studied as inhibitors of rat liver mitochondrial swelling and O(2) uptake by ascorbic acid-dependent lipid peroxidation (LP) and as modulators of mitochondrial swelling induced by Na(+)-linoleate or Na(+)-pyrophosphate. 1,4-DHPs studied include 4-unsubstituted and 4-methyl- and 4-phenyl-substituted 3, 5-dialkoxycarbonylderivatives of 2,6-dimethyl-1,4-DHP with variations in alkoxy chain length and composition, 4-unsubstituted and 4-methyl-, 4-aryl- and 4-pyridyl-substituted 3, 5-dianilidocarbonylderivatives, and a structurally related group of 3,5-dipyridylamidocarbonylderivatives. Many 1,4-DHPs possess marked antioxidant (AO) and membrane stabilizing activity, expressed as the mitochondrial swelling (deltaA(520)/t) and/or O(2) uptake rate decrease (V(0)/V) as well as prolongation of the induction period (tau/tau(0)) of mitochondrial swelling and/or O(2) uptake at ascorbic acid-dependent LP of rat liver mitochondria. 4-Unsubstituted 3,5-dialkoxycarbonyl-2,6-dimethyl-1,4-DHPs, as well as 4-unsubstituted or those possessing lipophylic 4-aryl- groups 3, 5-diamido-2,6-dimethyl-1,4-DHPs, reveal marked AO and membrane stabilizing properties. Oxidized (heteroaromatized) derivatives have minimal activity. Perhaps 1,4-DHPs preferably act as antioxidants on stages of initiation and prolongation of LP chain reactions at low concentrations: IC(50) (when V(0)/V or tau/tau(0)=2) are 0.1 microM to 100 microM. At 100 microM 3,5-di-p-hydroxyphenoxycarbonyl- and 3, 5-di-p-tolyloxycarbonyl-2,6-dimethyl-1,4-DHPs, as well as 3, 5-diethoxycarbonyl-2,6-dimethylpyridine (oxidized form of Hantzsch ester) and 3,5-diamyloxycarbonyl-2,6-dimethylpyridine, alter the mitochondrial swelling rate in the presence of natural protonophore Na(+)-linoleate (0.063 mM and 0.125 mM). 3,5-Di-n-butyloxycarbonyl-2, 6-dimethyl-1,4-DHP at 100 microM completely stops mitochondrial swelling in the presence of 0.8 mM Na(+)-pyrophosphate. In the presence of many of the 1,4-DHPs, the lipid peroxidation process was inhibited. However, the swelling process could be prolonged, promoted, accelerated or inhibited-depending on 1,4-DHPs structure, concentration, the type of initiators of the swelling process and the medium composition.     

A possible role for calmodulin in Ca2+-induced swelling of mitochondria

Ca2+-induced mitochondrial swelling was inhibited by a low concentration of calmodulin antagonists. Two affinities of Ca2+ to mitochondrial swelling were observed: high (2-5 microM) and low (more than 100 microM) systems. The high-affinity change was inhibited by micromolar level of trifluoperazine and W-7, but not by W-5. The possible mechanism of this inhibition and the role of CaM in mitochondria are discussed.     

Matrix magnesium and the permeability of heart mitochondria to potassium ion

Isolated beef heart mitochondria were treated with A23187 in the presence of different concentrations of Mg2+ or EDTA to establish varying levels of total mitochondrial Mg2+. The Mg2+ content was related to the rate of passive swelling of the mitochondria in potassium acetate and other potassium salts in which swelling is presumed to depend on K+ entry via an endogenous K+/H+ antiport. Swelling in these salts does not commence until Mg2+ has been depleted from an initial value of 36 nmol X mg-1 of protein to 8 nmol/mg-1, or less. Below this level, swelling increases linearly with decreasing Mg2+ to a maximum rate at 2 nmol of Mg2+ X mg-1. Rotenone-treated heart mitochondria suspended in 75 mM potassium acetate at pH 7.80 show no delta pH by 5,5-dimethyl-2,4-oxazolidinedione distribution. Distribution of methylamine also shows essentially no delta pH under these conditions when allowance is made for binding of [14C]methylamine by mitochondrial membranes under these conditions. Addition of A23187 results in a small and transient delta pH (delta pH less than 0.14, acid interior) as measured by methylamine distribution. Estimation of the maximum matrix free Mg2+ concentration from the maximum delta pH observed and the external free Mg2+ concentration at equilibrium with A23187 shows that swelling is not initiated until matrix free Mg2+ is decreased to below 150 microM. An independent estimate of free Mg2+ using a null-point procedure gives a lower, but quite similar value (50 microM) for maximum matrix free Mg2+ when swelling commences. The large depletion of total and free Mg2+ that is required to activate swelling in potassium acetate (and presumably K+/H+ antiport activity) does not appear to be compatible with previous indications that free Mg2+ acts as a "carrier brake" to regulate K+ extrusion from the mitochondrion on such an antiport (Garlid, K. D. (1980) J. Biol. Chem. 255, 11273-11279). The removal of a tightly bound component of mitochondrial Mg2+ is closely related to increased K+ permeability and increased passive swelling in potassium salts. This Mg2+ appears to play a role in the maintenance of mitochondrial membrane structure and integrity.     

Identification of the ubiquinone-binding site of NADH:ubiquinone oxidoreductase (complex I) from Neurospora crassa.

In order to localize the ubiquinone-binding site of complex I (NADH:ubiquinone oxidoreductase), a novel photoreactive ubiquinone analogue (Q0C7ArN3) has been synthesized. It is shown that the direct chemical precursor of this analogue (Q0C7ArNO2) and the analogue itself are accepted as substrates in an enzyme assay utilizing ubiquinone-depleted mitochondrial membranes of Neurospora crassa. The activity of the enzyme applying these derivatives is inhibited by 50% at a concentration of 9 and 20 microM rotenone. Photoaffinity labeling experiments were performed with both isolated complex I and whole mitochondrial membranes of N. crassa under various conditions. In each of these experiments a protein subunit with an apparent molecular mass of about 9.5 kDa was labeled with high specificity. Radioactive labeling was totally prevented by the addition of ubiquinone-2 at concentrations higher than 500 microM but was not affected by comparable concentrations of rotenone or other hydrophobic substances. In the labeling experiments using whole membranes, the labeling signal was dramatically increased in the presence of 1.5 mM NADH. These results strongly suggest that the ubiquinone analogue interacts specifically with the enzyme.     

Screening assays for the mitochondrial permeability transition using a fluorescence multiwell plate reader

Opening of permeability transition (PT) pores in the mitochondrial inner membrane causes the mitochondrial permeability transition (MPT) and leads to mitochondrial swelling, membrane depolarization, and release of intramitochondrial solutes. Here, our aim was to develop high-throughput assays using a fluorescence plate reader to screen potential inducers and blockers of the MPT. Isolated rat liver mitochondria (0.5 mg/ml) were incubated in multiwell plates with tetramethylrhodamine methyl ester (TMRM, 1 microM), a potential-indicating fluorophore, and Fluo-5N (1 microM), a low-affinity Ca(2+) indicator. Incubation led to mitochondrial polarization, as indicated by uncoupler-sensitive quenching of the red TMRM fluorescence. CaCl(2) (100 microM) addition led to ruthenium red-sensitive mitochondrial Ca(2+) uptake, as indicated by green Fluo-5N fluorescence. After Ca(2+) accumulation, mitochondria depolarized, released Ca(2+) into the medium, and began to swell. This swelling was monitored as a decrease in light absorbance at 620 nm. Swelling, depolarization, and Ca(2+) release were prevented by cyclosporin A (1 microM), confirming that these events represented the MPT. Measurements of Ca(2+), mitochondrial membrane potential, and swelling could be made independently from the same wells without cross interference, and all three signals could be read from every well of a 48-well plate in about 1 min. In other experiments, mitochondria were ester-loaded with carboxydichlorofluorescein (carboxy-DCF) during the isolation procedure. Release of carboxy-DCF after PT pore opening led to an unquenching of green carboxy-DCF fluorescence occurring simultaneously with swelling. By combining measurements of carboxy-DCF release, Ca(2+) uptake, membrane potential, and swelling, MPT inducers and blockers can be distinguished from uncouplers, respiratory inhibitors, and blockers of Ca(2+) uptake. This high-throughput multiwell assay is amenable for screening panels of compounds for their ability to promote or block the MPT.     

Calcium uptake by intracellular compartments in permeabilised enterocytes. Effect of inositol 1,4,5 trisphosphate

Treatment of rat small intestine with EDTA produced isolated enterocytes with plasma membranes which were permeable to small ions. When resuspended in a medium designed to resemble the intracellular medium, Ca2+ was accumulated into the cells. Both mitochondrial and a non-mitochondrial (presumably endoplasmic reticulum) compartments were responsible for sequestering the cation, as indicated by the effects of the mitochondrial inhibitors oligomycin and antimycin and of the Ca-ATPase inhibitor sodium orthovanadate assayed at low (0.9 microM) and high (12 microM) free Ca2+ concentrations. Addition of inositol (1,4,5) trisphosphate induced a rapid release of Ca2+ from the non mitochondrial compartment. The effect of inositol trisphosphate was concentration dependent and showed 50% of maximal release at 2 M. Neither cyclic AMP nor dibutyryl cyclic AMP caused release of Ca2+. These findings lend novel support to the possibility that Ca-mediated control of ionic transport in the small intestine is exerted through the phosphatidylinositol-protein kinase C transduction mechanism.     

Protective effect of the plasticizer di(2-ethylhexyl) phthalate against damage of the mitochondrial membrane induced by calcium: possible participation of the adenine nucleotide translocator

The effect of di(2-ethylhexyl) phthalate (DEHP) on the response of isolated rat liver mitochondria to Ca2+ was investigated. DEHP was found to inhibit more than 60% of the auto-accelerating release of respiration induced by 100 microM Ca2+, being maximally inhibitory at 40 microM. Prior addition of DEHP also partially inhibited Ca2+-induced swelling of the mitochondrial matrix. However, DEHP did not change the net rate of Ca2+ uptake measured by the steady-state infusion method. DEHP also reduced the rate of adenine nucleotide exchange across the mitochondrial membrane. Another alkyl phthalate and alkyl citrates had similar effects on Ca2+-induced membrane damage, but their potencies depended on the lengths of their alkyl chains. These results suggest that the effects of DEHP and other alkyl esters on mitochondrial functions are mainly based on their actions on membrane lipids surrounding adenine nucleotide translocator (AdNT), resulting in alteration of the interaction between these phospholipids and AdNT, and consequent modification of the state of the protein.     

Gold complexes inhibit mitochondrial thioredoxin reductase: consequences on mitochondrial functions

The effects of gold(I) complexes (auranofin, triethylphosphine gold and aurothiomalate), gold(III) complexes ([Au(2,2'-diethylendiamine)Cl]Cl(2), [(Au(2-(1,1-dimethylbenzyl)-pyridine) (CH(3)COO)(2)], [Au(6-(1,1-dimethylbenzyl)-2,2'-bipyridine)(OH)](PF(6)), [Au(bipy(dmb)-H)(2,6-xylidine)](PF(6))), metal ions (zinc and cadmium acetate) and metal complexes (cisplatin, zinc pyrithione and tributyltin) on mitochondrial thioredoxin reductase and mitochondrial functions have been examined. Both gold(I) and gold(III) complexes are extremely efficient inhibitors of thioredoxin reductase showing IC(50) ranging from 0.020 to 1.42 microM while metal ions and complexes not containing gold are less effective, exhibiting IC(50) going from 11.8 to 76.0 microM. At variance with thioredoxin reductase, auranofin is completely ineffective in inhibiting glutathione peroxidase and glutathione reductase, while gold(III) compounds show some effect on glutathione peroxidase. The mitochondrial respiratory chain is scarcely affected by gold compounds while the other metal complexes and metal ions, in particular zinc ion and zinc pyrithione, show a more marked inhibitory effect that is reflected on a rapid induction of membrane potential decrease that precedes swelling. Therefore, differently from gold compounds, the various metal ions and metal complexes exert their effect on different targets indicating a lower specificity. It is concluded that gold compounds are highly specific inhibitors of mitochondrial thioredoxin reductase and this action influences other functions such as membrane permeability properties. Metal ions and metal complexes markedly inhibit the activity of thioredoxin reductase although to an extent lower than that of gold compounds. They also inhibit mitochondrial respiration, decrease membrane potential and, finally, induce swelling.     

Partial inhibition by cyclosporin A of the swelling of liver mitochondria in vivo and in vitro induced by sub-micromolar [Ca2+], but not by butyrate. Evidence for two distinct swelling mechanisms.

1. The effects of cyclosporin A on the increase in matrix PPi and consequent swelling of energized liver mitochondria incubated with 1 mM-butyrate, 30 microM-bongkrekic acid or 0.1-35 microM-Ca2+ [Halestrap (1989) Biochim. Biophys. Acta 973, 355-382] were studied. 2. Cyclosporin (1 microM) had no significant effect on the swelling induced by butyrate, bongkrekic acid or Ca2+ at concentrations of less than 0.3 microM. 3. At higher [Ca2+] (greater than 0.3 microM), swelling became progressively inhibited by cyclosporin, although the increase in matrix PPi was slightly greater in the presence than in the absence of cyclosporin. 4. Titration with cyclosporin indicated that there are 128 pmol of relevant cyclosporin-binding sites per mg of mitochondrial protein, with a Ki of about 5 nM. 5. The decrease in light-scattering by hepatocytes induced by butyrate [Davidson & Halestrap (1988) Biochem. J. 254, 379-384] was unaffected by cyclosporin, whereas that induced by vasopressin was inhibited by 20-30% without a significant change in cellular PPi content. 6. It is suggested that there are two mechanisms for the increase in mitochondrial volume induced by Ca2+: a PPi-mediated mechanism that is insensitive to cyclosporin and an additional Ca2(+)-mediated effect that is inhibited by cyclosporin. The nature of these pathways and their inter-relationship is discussed in the following paper [Halestrap & Davidson (1990) Biochem. J. 268, 153-160].     

Mitochondrial inner membrane particles seen in sections ofin situ large amplitude swollen mitochondria in rhizodermal cells of cress (Lepidium sativum L.)

Addition of 5–40 mM sodium acetate to root explants of cress (Lepidium sativum L.) growing in a nutrient medium causes large amplitude swelling of mitochondria in rhizodermal cells. On the average, 10 mM sodium acetate causes a fourfold increase in mitochondrial volume, with 40 mM sodium acetate producing an up to tenfold increase in mitochondrial volume. During swelling, however, the mitochondrial membranes remain predominantly intact, and only the outer membrane occasionally appears to be broken. Two types of swelling can be observed: an overall swelling of mitochondrial matrices and a less frequent local swelling which leads to clearly different matrical regions. These regions may sometimes be separated by a septum formed from the inner mitochondrial membrane. After large amplitude swelling in 10 or 40 mM sodium acetate, the visibility of lollipop-like particles on the matrix side of inner mitochondrial membranes is strongly enhanced. These particles are suggested to be identical with mitochondrial inner membrane particles as visualized by negative staining. The distribution of these particles is described. Possible mechanisms which may cause enhanced visibility are discussed.     

Resveratrol-induced limitation of dysfunction of mitochondria isolated from rat brain in an anoxia-reoxygenation model

Resveratrol protection on the main functions of purified rat brain mitochondria submitted to anoxia-reoxygenation was investigated. Resveratrol (<0.1 microM) reversed partly (23.3%) the respiratory control ratio (RCR) decrease by protecting both states 3 and 4. This effect was both observed when resveratrol was added before anoxia or reoxygenation. Resveratrol fully inhibited the release of cytochrome c in a concentration-dependent manner and significantly decreased the superoxide anion (O2(0-)) production at a concentration of 1 nM. The mitochondrial membranes damaged after the anoxia-reoxygenation were partly protected (about 70%) by resveratrol at 0.1 microM. The oxygen consumption of mitochondria in presence of NADH and cytochrome c was significantly inhibited by resveratrol with a low EC50 of 18.34 pM. Resveratrol inhibited the CCCP-induced uncoupling from about 20%. The effects of resveratrol on oxidative phosphorylation parameters were also investigated in rats after pretreatment (0.4, 2 and 10 mg/kg/day) for one week. After the isolation of brain mitochondria, the RCR was significantly less decreased in the resveratrol group compared to the control group. These results showed that resveratrol could preserve the mitochondrial functions with at least three mechanisms: antioxidant properties, action on complex III and a membrane stabilizing effect.     

Duramycin effects on the structure and function of heart mitochondria. II. Energy conversion reactions.

The polypeptide antibiotic duramycin has been reported to interact selectively with phosphatidylethanolamine (PE) and monogalactosyldiacylglycerol (Navarro et al., 1985, Biochemistry 24, 4645-4650). PE is a major component of mitochondrial membranes. Duramycin was used to probe the role of PE in mitochondrial energy conversion reactions with the following results: (i) Duramycin uncoupled mitochondrial respiration, decreasing the respiratory control ratio to 1 at 5 microM. At concentrations of duramycin in excess of 10 microM, ADP addition inhibited electron transport. (ii) Duramycin inhibited oxidative phosphorylation (C50 less than 2 microM). (iii) Duramycin stimulated mitochondrial ATP hydrolysis modestly. The antibiotic was 7- to 16-fold less effective in this regard than concentrations of carbonylcyanide p-trifluoromethoxyphenylhydrazone (F-CCP) which produced comparable uncoupling. (iv) Duramycin inhibited uncoupled ATPase activity (C50 = 8 microM). Inhibition of the ATPase activity of intact mitochondria was blocked by 1 mM MgCl2 and 5 mM CaCl2; inhibition persisted in sub-mitochondrial particles assayed in the presence of 3 mM MgCl2. The effects on mitochondrial function of free fatty acids (FFA) and duramycin are similar in many respects. It is suggested that duramycin, like FFA, uncouples via a nonclassical mechanism, possibly by disrupting intramembrane H+ transfer between redox and ATPase complexes. In addition, interaction of duramycin, either direct or indirect, with the F0 moiety of the mitochondrial ATPase and with one or more components of the respiratory electron transport chain is proposed.     

Inhibition by [corrected] ursolic acid of [corrected] calcium-induced mitochondrial permeability transition and release of two proapoptotic proteins

The possible inhibition by [corrected] ursolic acid (UA) of [corrected] mitochondrial permeability transition (MPT) in mouse liver was investigated to identify the mechanisms underlying the hepatoprotective effect of UA. The effect of UA on liver MPT induced by Ca2+ was assessed by measuring changes in mitochondrial volume, mitochondrial membrane potential (MMP), release of matrix Ca2+, and transfer of cytochrome c (Cyt c) and apoptosis-inducing factor (AIF) from the intermembrane space to the cytoplasm. The results showed that obvious mitochondrial swelling, loss of MMP, and release of matrix Ca2+ occurred after the addition of 50 microM Ca2+. However, preincubation with 20, 50 or 100 microg ml(-1) UA significantly blocked the above changes. Addition of 100 microg ml(-1) UA inhibited on mitochondrial swelling by 73.2% after 5 min, while the MMP dissipating and Ca2+ releasing were, respectively, suppressed by 59.3% and 54.1% after 3 min. In addition, Western blot analysis showed Cyt c and AIF transferred from mitochondrial pellet to the supernatant after the addition of 50 microM Ca2+, but the process was significantly inhibited by various concentrations of UA. The results suggest that the mechanisms underlying the hepatoprotection of UA may be related to its direct inhibitory action on MPT.