Ion permeability induction by the SH cross-linking reagents in rat liver mitochondria is inhibited by the free radical scavenger, butylhydroxytoluene

Mitochondrial Oxidative Stress Is the General Reason for Apoptosis Induced by Different-Valence Heavy Metals in Cells and Mitochondria

This review analyzes the causes and consequences of apoptosis resulting from oxidative stress that occurs in mitochondria and cells exposed to the toxic effects of different-valence heavy metals (Ag+, Tl+, Hg2+, Cd2+, Pb2+, Al3+, Ga3+, In3+, As3+, Sb3+, Cr6+, and U6+). The problems of the relationship between the integration of these toxic metals into molecular mechanisms with the subsequent development of pathophysiological processes and the appearance of diseases caused by the accumulation of these metals in the body are also addressed in this review. Such apoptosis is characterized by a reduction in cell viability, the activation of caspase-3 and caspase-9, the expression of pro-apoptotic genes (Bax and Bcl-2), and the activation of protein kinases (ERK, JNK, p53, and p38) by mitogens. Moreover, the oxidative stress manifests as the mitochondrial permeability transition pore (MPTP) opening, mitochondrial swelling, an increase in the production of reactive oxygen species (ROS) and H2O2, lipid peroxidation, cytochrome c release, a decline in the inner mitochondrial membrane potential (ΔΨmito), a decrease in ATP synthesis, and reduced glutathione and oxygen consumption as well as cytoplasm and matrix calcium overload due to Ca2+ release from the endoplasmic reticulum (ER). The apoptosis and respiratory dysfunction induced by these metals are discussed regarding their interaction with cellular and mitochondrial thiol groups and Fe2+ metabolism disturbance. Similarities and differences in the toxic effects of Tl+ from those of other heavy metals under review are discussed. Similarities may be due to the increase in the cytoplasmic calcium concentration induced by Tl+ and these metals. One difference discussed is the failure to decrease Tl+ toxicity through metallothionein-dependent mechanisms. Another difference could be the decrease in reduced glutathione in the matrix due to the reversible oxidation of Tl+ to Tl3+ near the centers of ROS generation in the respiratory chain. The latter may explain why thallium toxicity to humans turned out to be higher than the toxicity of mercury, lead, cadmium, copper, and zinc.

Effects of Tl+ on the inner membrane thiol groups, respiration, and swelling in succinate-energized rat liver mitochondria were modified by thiol reagents

The effects of both Tl⁺ and thiol reagents were studied on the content of the inner membrane free SH-groups, detected with Ellman reagent, and the inner membrane potential as well as swelling and respiration of succinate-energized rat liver mitochondria in medium containing TlNO₃ and KNO₃. These effects resulted in a rise in swelling and a decrease in the content, the potential, and mitochondrial respiration in 3 and 2,4-dinitrophenol-uncoupled states. A maximal effect was seen when phenylarsine oxide reacting with thiol groups recessed into the hydrophobic regions of the membrane. Compared with phenylarsine oxide, the effective concentrations of other reagents were approximately one order of magnitude higher in experiments with mersalyl and 4,4'-diisothiocyanostilbene-2,2'-disulfonate, and two orders of magnitude higher in experiments with tert-butyl hydroperoxide and diamide. The above effects of Tl⁺ and the thiol reagents became even more pronounced with calcium overload of mitochondria. However, the effects were suppressed by inhibitors of the mitochondrial permeability transition pore (cyclosporine A, ADP, and n-ethylmaleimide). These findings suggest that opening of the pore induced by Tl⁺ in the inner membrane can be dependent on the conformation state of the adenine nucleotide translocase, which depends on the activity of its thiol groups.

Titration of lysine residues on adenine nucleotide translocase by fluorescamine induces permeability transition

Chemical modification of primary amino groups of mitochondrial membrane proteins by the fluorescent probe fluorescamine induces non-specific membrane permeabilisation. Titration of the lysine ϵ-amino group promoted efflux of accumulated Ca(2+), collapse of transmembrane potential and mitochondrial swelling. Ca(2+) release was inhibited by cyclosporin A. Considering the latter, we assumed that fluorescamine induces permeability transition. Carboxyatractyloside also inhibited the reaction. Using a polyclonal antibody for adenine nucleotide translocase, Western blot analysis showed that the carrier appeared labelled with the fluorescent probe. The results point out the importance of the ϵ-amino group of lysine residues, located in the adenine nucleotide carrier, on the modulation of membrane permeability, since its blockage suffices to promote opening of the non-specific nanopore.

Mitochondrial free [Ca2+] levels and the permeability transition

Mitochondrial Ca(2+) activates many processes, from mitochondrial metabolism to opening of the permeability transition pore (PTP) and apoptosis. However, there is considerable controversy regarding the free mitochondrial [Ca(2+)] ([Ca(2+)](M)) levels that can be attained during cell activation or even in mitochondrial preparations. Studies using fluorescent dyes (rhod-2 or similar), have reported that phosphate precipitation precludes [Ca(2+)](M) from increasing above 2-3 microM. Instead, using low-Ca(2+)-affinity aequorin probes, we have measured [Ca(2+)](M) values more than two orders of magnitude higher. We confirm here these values by making a direct in situ calibration of mitochondrial aequorin, and we show that a prolonged increase in [Ca(2+)](M) to levels of 0.5-1mM was actually observed at any phosphate concentration (0-10mM) during continuous perfusion of 3.5-100 microM Ca(2+)-buffers. In spite of this high and maintained (>10 min) [Ca(2+)](M), mitochondria retained functionality and the [Ca(2+)](M) drop induced by a protonophore was fully reversible. In addition, this high [Ca(2+)](M) did not induce PTP opening unless additional activators (phenyl arsine oxide, PAO) were present. PAO induced a rapid, concentration-dependent and irreversible drop in [Ca(2+)](M). In conclusion [Ca(2+)](M) levels of 0.5-1mM can be reached and maintained for prolonged periods (>10 min) in phosphate-containing medium, and massive opening of PTP requires additional pore activators.

Redox-regulated ion channel activity of a cysteine-containing gramicidin A analogue

According to recent data, gramicidin A analogues having positively charged amino acid sequences at the C-termini exhibit two types of channel activity in lipid membranes: classical cation-selective channels and large unselective pores. The induction of unselective pores was shown here to strongly depend on the redox state of the membrane-bathing solution, if the gramicidin analogue contained a cysteine residue in the sequence GSGPKKKRKVC attached to the C-terminus. In particular, the addition of H2O2 led to an increase in the transmembrane current and the loss of cationic selectivity on planar bilayer lipid membranes and an increase in the carboxyfluorescein leakage of liposomes. The effect was observed at high concentration of the peptide while was absent at the single-channel level. It was concluded that oxidation led to possible formation of dimers of the peptide, which promoted the formation of large unselective pores.

Comparative kinetic analysis reveals that inducer-specific ion release precedes the mitochondrial permeability transition

Relationships among the multiple events that precede the mitochondrial membrane permeability transition (MPT) are not yet clearly understood. A combination of newly developed instrumental and computational approaches to this problem is described. The instrumental innovation is a high-resolution digital apparatus for the simultaneous, real-time measurement of four mitochondrial parameters as indicators of the respiration rate, membrane potential, calcium ion transport, and mitochondrial swelling. A computational approach is introduced that tracks the fraction of mitochondria that has undergone pore opening. This approach allows multiple comparisons on a single time scale. The validity of the computational approach for studying complex mitochondrial phenomena was evaluated with mitochondria undergoing an MPT induced by Ca(2+), phenylarsine oxide or alamethicin. Selective ion leaks were observed that precede the permeability transition and that are inducer specific. These results illustrate the occurrence of inducer-specific sequential changes associated with the induction of the permeability transition. Analysis of the temporal relationship among the multiple mitochondrial parameters of isolated mitochondria should provide insights into the mechanisms underlying these responses.

Positively charged ceramide is a potent inducer of mitochondrial permeabilization

Ceramide-induced cell death is thought to be mediated by change in mitochondrial function, although the precise mechanism is unclear. Proposed models suggest that ceramide induces cell death through interaction with latent binding sites on the outer or inner mitochondrial membranes, followed by an increase in membrane permeability, as an intermediate step in ceramide signal propagation. To investigate these models, we developed a new generation of positively charged ceramides that readily accumulate in isolated and in situ mitochondria. Accumulated, positively charged ceramides increased inner membrane permeability and triggered release of mitochondrial cytochrome c. Furthermore, the positively charged ceramide-induced permeability increase was suppressed by cyclosporin A (60%) and 1,3-dicyclohexylcarbodiimide (90%). These observations suggest that the inner membrane permeability increase is due to activation of specific ion transporters, not the generalized loss of lipid bilayer barrier functions. The difference in sensitivity of ceramide-induced ion fluxes to inhibitors of mitochondrial transporters suggests activation of at least two transport systems: the permeability transition pore and the electrogenic H(+) channel. Our results indicate the presence of specific ceramide targets in the mitochondrial matrix, the occupation of which triggers permeability alterations of the inner and outer mitochondrial membranes. These findings also suggest a novel therapeutic role for positively charged ceramides.

Protection of tamoxifen against oxidation of mitochondrial thiols and NAD(P)H underlying the permeability transition induced by prooxidants

The effects of tamoxifen (TAM) were studied on the mitochondrial permeability transition (MPT) induced by the prooxidant tert-butyl hydroperoxide (t-BuOOH) or the thiol cross-linker phenylarsine oxide (PhAsO), in the presence of Ca2+, in order to clarify the mechanisms involved in the MPT inhibition by this drug. The combination of Ca2+ with t-BuOOH or PhAsO induces mitochondrial swelling and depolarization of membrane potential (deltapsi). These events are inhibited by cyclosporine A (CyA), suggesting the inhibition of the MPT. The pre-incubation of mitochondria with TAM also prevents those events and induces a time-dependent reversal of deltapsi depolarization following MPT induction, similarly to CyA. Moreover, TAM inhibits the Ca2+ release and the oxidation of NAD(P)H and protein thiol (-SH) groups promoted by t-BuOOH plus Ca2+. On the other hand, the MPT induced by PhAsO plus Ca2+ does not induce -SH groups oxidation, supporting the notion that MPT induction by this compound is not mediated by the oxidation of specific membrane proteins groups. However, TAM also inhibits the PhAsO induced MPT, suggesting that this drug may inhibit this phenomenon by inhibiting PhAsO binding to -SH vicinal groups, implicated in the MPT induction. These data indicate that the MPT inhibition by TAM may be related to its antioxidant capacity in preventing the oxidation of NAD(P)H and -SH groups or by blocking these groups, since the oxidation of these groups increases the sensitivity of mitochondria to the MPT induction. Additionally, they suggest an MPT-independent pathway for TAM-induced apoptosis and a potential ER-independent mechanism for the effectiveness of this drug in the cancer therapy and prevention.

The characterization of mitochondrial permeability transition in clonal pancreatic beta-cells. Multiple modes and regulation

Mitochondrial permeability transition (MPT), which contributes substantially to the regulation of normal mitochondrial metabolism, also plays a crucial role in the initiation of cell death. It is known that MPT is regulated in a tissue-specific manner. The importance of MPT in the pancreatic beta-cell is heightened by the fact that mitochondrial bioenergetics serve as the main glucose-sensing regulator and energy source for insulin secretion. In the present study, using MIN6 and INS-1 beta-cells, we revealed that both Ca(2+)-phosphate- and oxidant-induced MPT is remarkably different from other tissues. Ca(2+)-phosphate-induced transition is accompanied by a decline in mitochondrial reactive oxygen species production related to a significant potential dependence of reactive oxygen species formation in beta-cell mitochondria. Hydroperoxides, which are indirect MPT co-inducers active in liver and heart mitochondria, are inefficient in beta-cell mitochondria, due to the low mitochondrial ability to metabolize them. Direct cross-linking of mitochondrial thiols in pancreatic beta-cells induces the opening of a low conductance ion permeability of the mitochondrial membrane instead of the full scale MPT opening typical for liver mitochondria. Low conductance MPT is independent of both endogenous and exogenous Ca(2+), suggesting a novel type of nonclassical MPT in beta-cells. It results in the conversion of electrical transmembrane potential into DeltapH instead of a decrease in total protonmotive force, thus mitochondrial respiration remains in a controlled state. Both Ca(2+)- and oxidant-induced MPTs are phosphate-dependent and, through the "phosphate flush" (associated with stimulation of insulin secretion), are expected to participate in the regulation in beta-cell glucose-sensing and secretory activity.

The natural antioxidant otobaphenol delays the permeability transition of mitochondria and induces their aggregation

The lignan otobaphenol, (8R,8'R,7R)-4'-hydroxy-5'-methoxy-3,4-methylenedioxy-2',7,8,8'-neolignan, extracted from Virola Aff. Pavonis leaves, completely inhibits at a concentration of 2.5 micro M the Fe(3+)-ascorbate-induced lipoperoxidation of rat liver mitochondria that was determined by oxygen consumption and accumulation of thiobarbituric acid-reactive species. At 25 micro M, it delays the mitochondrial permeability transition induced by tert-butyl hydroperoxide or Ca(2+), substantially inhibits the state 3 respiration, does not affect the state 4 respiration and the ADP/O ratio (with succinate), diminishes the rate of Ca(2+) uptake by mitochondria, and delays the ruthenium red-insensitive uncoupler-induced release of the loaded Ca(2+). Dose-dependent delaying of the calcium-induced swelling of mitochondria in the presence of otobaphenol nonlinearly correlates with its 1,1-diphenyl-2-picrylhydrazyl free radical scavenging activity. At 75 micro M and higher, this lignan causes mitochondrial aggregation and is able to aggregate itself, without mitochondria. The formed aggregates of otobaphenol do not cause an aggregation of subsequently added mitochondria. Thus, otobaphenol seems to be a promising target to prevent the oxidative stress death of cells.

Cyclosporin A-sensitive permeability transition pore is involved in Cd(2+)-induced dysfunction of isolated rat liver mitochondria: doubts no more

There is dose-dependent Cd(2+)-evoked swelling of isolated rat liver mitochondria energized by complex I, II, or IV respiratory substrates in sucrose medium in the absence of added Ca(2+) and P(i), which is prevented by Sr(2+). Permeability transition effectors (ADP, CsA, EGTA, RR, DTT, ATR, P(i), and Ca(2+)) affect in a corresponding way Cd(2+)-promoted membrane permeabilization in NH(4)NO(3), KCl, and sucrose media. Maximal depression of Cd(2+)-induced swelling is achieved by simultaneous addition of ADP, Mg(2+), and CsA that produces either synergistic (NH(4)NO(3)) or additive (KCl and sucrose media) action. Sustained activation by low [Cd(2+)] of mitochondrial basal respiration in KCl medium is observed both in the absence and in the presence of rotenone and/or oligomycin but only in the latter case (rotenone+oligomycin) CsA inhibits completely Cd(2+) activation of St 4 respiration and partially reverses DNP-uncoupled respiration depressed by cadmium. Cd(2+) effects are discussed in terms of comparison with those of Zn(2+) and PhAsO.

Biphasic oxidation of mitochondrial NAD(P)H

The redox state of mitochondrial pyridine nucleotides is known to be important for structural integrity of mitochondria. In this work, we observed a biphasic oxidation of endogenous NAD(P)H in rat liver mitochondria induced by tert-butylhydroperoxide. Nearly 85% of mitochondrial NAD(P)H was rapidly oxidized during the first phase. The second phase of NAD(P)H oxidation was retarded for several minutes, appearing after the inner membrane potential collapse and mitochondria swelling. It was characterized by disturbance of ATP synthesis and dramatic permeabilization of the inner membrane to pyridine nucleotides. The second phase was completely prevented by 0.5 microM cyclosporin A or 0.2 mM EGTA or was significantly delayed by 25 microM butylhydroxytoluene or trifluoperazine. The obtained data suggest that the second phase resulted from oxidation of the remaining NADH via the outer membrane electron transport system of permeabilized mitochondria, leading to further oxidation of the remaining NADPH in a transhydrogenase reaction.

Possible involvement of the adenine nucleotide translocase in the activation of the permeability transition pore induced by cadmium

Low levels of cadmium induce a rapid calcium efflux in energized rat kidney mitochondria. This is accompanied by the collapse of the transmembrane gradient in a partial CSA-sensitive fashion. The binding of 109Cd2+ to mitochondria is a saturable function; in the presence of NEM, the binding of 2.5 nmol 109Cd2+/mg of protein suffices to induce the opening of the permeability transition pore. It was found that cadmium bound mainly to proteins of molecular weight between 30 and 50 kDa. In the presence of the monothiol reagent NEM, the label is concentrated in the 30 kDa protein. Following the addition of the reducing agent dithiothreitol, calcium is reaccumulated and the membrane potential restored. This correlates with a significant loss of label in the 30 kDa protein region. The 30 kDa protein was identified as the adenine nucleotide translocase by labelling experiments with eosin 5-maleimide and experiments of reconstitution.

Gradual changes in permeability of inner mitochondrial membrane precede the mitochondrial permeability transition

Some compounds are known to induce solute-nonselective permeability of the inner mitochondrial membrane (IMM) in Ca2+-loaded mitochondria. Existing data suggest that this process, following the opening of a mitochondrial permeability transition pore, is preceded by different solute-selective permeable states of IMM. At pH 7, for instance, the K0.5 for Ca2+-induced pore opening is 16 microM, a value 80-fold above a therapeutically relevant shift of intracellular Ca2+ during ischemia in vivo. The present work shows that in the absence of Ca2+, phenylarsine oxide and tetraalkyl thiuram disulfides (TDs) are able to induce a complex sequence of IMM permeability changes. At first, these agents activated an electrogenic K+ influx into the mitochondria. This K+-specific pathway had K0.5 = 35 mM for K+ and was inhibited by bromsulfalein with Ki = 2.5 microM. The inhibitors of mitochondrial KATP channel, ATP and glibenclamide, did not inhibit K+ transport via this pathway. Moreover, 50 microM glibenclamide induced by itself K+ influx into the mitochondria. After the increase in K+ permeability of IMM, mitochondria become increasingly permeable to protons. Mechanisms of H+ leak and nonselective permeability increase could also be different depending on the type of mitochondrial permeability transition (MPT) inducer. Thus, permeabilization of mitochondria induced by phenylarsine oxide was fully prevented by ADP and/or cyclosporin A, whereas TD-induced membrane alterations were insensitive toward these inhibitors. It is suggested that MPT in vivo leading to irreversible apoptosis is irrelevant in reversible ischemia/reperfusion injury.

Mitochondrial permeability transition as induced by cross-linking of the adenine nucleotide translocase

Mitochondrial permeability transition is caused by the opening of a transmembrane pore whose chemical nature has not been well established yet. The present work was aimed to further contribute to the knowledge of the membrane entity comprised in the formation of the non-specific channel. The increased permeability was established by analyzing the inability of rat kidney mitochondria to take up and accumulate Ca2+, as well as their failure to build up a transmembrane potential, after the cross-linking of membrane proteins by copper plus ortho-phenanthroline. To identify the cross-linked proteins, polyacrylamide gel electrophoresis was performed. The results are representative of at least three separate experiments. It is indicated that 30 microM Cu2+ induced the release of 4.3 nmol Ca2+ per mg protein. However, in the presence of 100 microM ortho-phenanthroline only 2 microM Cu2+ was required to attain the total release of the accumulated Ca2+; it should be noted that such a reaction is not inhibited by cyclosporin. The increased permeability corresponds to cross-linking of membrane proteins in which approximately 4 nmol thiol groups per mg protein appear to be involved. Such a linking process is inhibited by carboxyatractyloside. By using the fluorescent probe eosin-5-maleimide the label was found in a cross-linking 60 kDa dimer of two 30 kDa monomers. From the data presented it is concluded that copper-o-phenanthroline induces the intermolecular cross-linking of the adenine nucleotide translocase which in turn is converted to non-specific pore.

The Ca2+ -induced pore opening in mitochondria energized by succinate-ferricyanide electron transport

The oxygen dependence of the mitochondria permeability transition pore was under study in non-respiring rat liver mitochondria. Oxygen in the medium was depleted by saturation of the incubation medium with N2 and spontaneously by mitochondrial respiration followed by the addition of glucose/glucose oxidase. After the anaerobic state had been reached, ferricyanide has been added to support succinate-driven energization in the absence of oxygen. In the other set of the experiments KCN was added to block operation of the respiratory chain under aerobic conditions. Again, ferricyanide was added as an electron acceptor. Superoxide dismutase was added to trap superoxide anion radicals. Under either hypoxic conditions or in the presence of cyanide, calcium ions were shown to induce the permeability transition. The concentration of Ca2+ required was lower than under conditions of active respiration. In both cases, the transition was prevented by cyclosporine A.

Properties of a cyclosporin-insensitive permeability transition pore in yeast mitochondria

Yeast mitochondria (Saccharomyces cerevisiae) contain a permeability transition pore which is regulated differently than the pore in mammalian mitochondria. In a mannitol medium containing 10 mM Pi and ethanol (oxidizable substrate), yeast mitochondria accumulate large amounts of Ca2+ (>400 nmol/mg of protein) upon the addition of an electrophoretic Ca2+ ionophore (ETH129). Pore opening does not occur following Ca2+ uptake, even though ruthenium red-inhibited rat liver mitochondria undergo rapid pore opening under analogous conditions. However, a pore does arise in yeast mitochondria when Ca2+ and Pi are not present, as monitored by swelling, ultrastructure, and matrix solute release. Pore opening is slow unless a respiratory substrate is provided (ethanol or NADH) but also occurs rapidly in response to ATP (2 mM) when oligomycin is present. Pi and ADP inhibit pore opening (EC50 approximately 1 and 4 mM, respectively), however, cyclosporin A (7 microg/ml), oligomycin (20 microg/ml), or carboxyatractyloside (25 microM) have no effect. The pore arising during respiration is also inhibited by nigericin or uncoupler, indicating that an acidic matrix pH antagonizes the process. Pi also inhibits pore opening by lowering the matrix pH (Pi/OH- antiport). However, inhibition of the ATP-induced pore by Pi is seen in the presence of mersalyl, suggesting a second mechanism of action. Since pore induction by ATP is not sensitive to carboxyatractyloside, ATP appears to act at an external site and Pi may antagonize the interaction. Isoosmotic polyethylene glycol-induced contraction of yeast mitochondria swollen during respiration, or in the presence of ATP, is 50% effective at a solute size of 1.0-1.1 kDa. This suggests that the same pore is induced in both cases and is comparable in size with the permeability transition pore of heart and liver mitochondria.

Effect of butylhydroxytoluene and related compounds on permeability of the inner mitochondrial membrane

Mitochondrial inner membrane contains a latent pore (PTP) that when opened uncouples mitochondrial energy transduction and allows rapid equilibration of low-molecular-weight solutes between the matrix and exterior. Based on sensitivity of the PTP to well-known free radical scavenger butylhydroxytoluene (BHT), it has been proposed that increased steady-state level of oxygen radicals, and subsequent radical attack of proteins and lipids, is a central event in activation of this pore (Novgorodov et al., J. Bioenerg. Biomembr. 19, 191-202, 1987; Carbonera and Azzone, Biochim. Biophys. Acta 943, 245-255, 1988). Present studies revealed that DBT, a derivative of BHT devoid of radical scavenging activity, exerts an analogous effect on the permeability of the inner membrane. Inhibition of the Ca2+-induced PTP opening is essentially complete at dose range of 50-60 nmol/mg protein with IC50 values of about 32 and 23 nmol/mg protein for DBT and BHT, respectively. Electron microscopy and osmotic experiments utilizing polyethylene glycols with different Stokes radii showed that the apparent lack of inhibition seen at high concentrations of these compounds results from cyclosporin A- and Ca2+-insensitive pore formation in the inner membrane. Experiments employing antioxidants with similar structure but dissimilar hydrophobicity provided evidence for localization of the antioxidant binding sites within the hydrophobic zone of the inner membrane or in the matrix space. The data obtained do not refute the notion that oxygen radicals modulate the PTP, but rather indicate that BHT operates independently of its free radical scavenging activity. Overall, the sensitivity to BHT and other antioxidants is not always a reliable criterion for the involvement of free radical reactions in the processes under study.

Mitochondrial membrane protein thiol reactivity with N-ethylmaleimide or mersalyl is modified by Ca2+: correlation with mitochondrial permeability transition

The content of mitochondrial membrane protein thiol groups accessible to react with the monofunctional thiol reagents mersalyl or N-ethylmaleimide (NEM) was determined using Ellman's reagent. Deenergized mitochondria incubated in the presence of Ca2+ (0-500 microM) undergo a very significant decrease in the content of membrane protein thiols accessible to NEM, and an increase in the content of thiols accessible to mersalyl. This process is time-dependent and inhibited by Mg2+, ruthenium red and ADP, but not by cyclosporin A. This suggests that Ca2+ binding to the inner mitochondrial membrane promotes extensive alterations in the conformation of membrane proteins that result in location changes of thiol groups. The relationship between these alterations and mitochondrial membrane permeability transition was studied through the effect of NEM and mersalyl on mitochondrial swelling induced by Ca2+ plus t-butyl hydroperoxide (t-bOOH) or Ca2+ plus the thiol cross-linkers 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS) or phenylarsine oxide (PhAsO). We observed that the hydrophobic thiol reagent NEM inhibits the effects of t-bOOH, DIDS and PhAsO, while the hydrophilic thiol reagent mersalyl inhibits only the effect of DIDS. Permeability transition in all the situations studied is accompanied by a significant decrease in the total membrane protein thiol content. In addition, mitochondrial membrane permeabilization induced by PhAsO is inhibited by EGTA, but not by ruthenium red. This result suggests that PhAsO leads to permeability transition through a mechanism independent of intramitochondrial Ca2(+)-induced alterations of thiol group reactivity, but dependent on Ca2+ binding to an extramitochondrial site. This site is sensitive to extramitochondrial Ca2+ concentrations in range of 1-50 microM.

Permeability transition pore of the inner mitochondrial membrane can operate in two open states with different selectivities

Prooxidants induce release of Ca2+ from mitochondria through the giant solute pore in the mitochondrial inner membrane. However, under appropriate conditions prooxidants can induce Ca2+ release without inducing a nonspecific permeability change. Prooxidant-induced release of Ca2+ is selective. Presumably, this is the result of the operation of a permeability pathway for H+ coupled to the reversal of the Ca2+ uniporter, the latter generating the selectivity. The solute pore and prooxidant-induced Ca2+-specific pathways exhibit common sensitivities to a set of inhibitors and activators. It is proposed that the pore can operate in two open states: (1) permeable to H+ only and (2) permeable to solutes of M(r) < 1500. Under some conditions, prooxidants induce the H+-selective state which, in turn, collapses the inner membrane potential and permits selective loss of Ca2+ via the Ca2+ uniporter.

Butylated hydroxytoluene and inorganic phosphate plus Ca2+ increase mitochondrial permeability via mutually exclusive mechanisms

Mitochondria undergo a permeability transition (PT)2, i.e., become nonselectively permeable to small solutes, in response to a wide range of conditions/compounds. In general, opening of the permeability transition pore (PTP) is Ca2+- and P(i)-dependent and is blocked by cyclosporin A (CsA), trifluoperazine (TFP), ADP, and butylated hydroxytoluene (BHT). Gudz and coworkers have reported [7th European Bioenergetics Conference, EBEC Short Reports (1992) 7, 125], however, that, under some conditions, BHT increases mitochondrial permeability via a process that may not share all of these characteristics. Specifically, they determined that the BHT-induced permeability transition was independent of Ca2+ and was insensitive to CsA. We have used mitochondrial swelling to compare in greater detail the changes in permeability induced by BHT and by Ca2+ plus P(i) with the following results. (1) The dependence of permeability on BHT concentration is triphasic: there is a threshold BHT concentration (ca. 60 nmol BHT/ mg mitochondrial protein) below which no increase occurs; BHT enhances permeability in an intermediate concentration range; and at high BHT concentrations (>120 nmol/mg) permeability is again reduced. (2) The effects of BHT depend on the ratio of BHT to mitochondrial protein. (3) Concentrations of BHT too low to induce swelling block the PT induced by Ca2+ and P(i). (4) The dependence of the Ca2+-triggered PT on P(i) concentration is biphasic. Below a threshold of 50-100 mu M, no swelling occurs. Above this threshold swelling increases rapidly. (5) P(i) levels too low to support the Ca2+-induced PT inhibit BHT-induced swelling. (6) Swelling induced by BHT can be stimulated by agents and treatments that block the PT induced by Ca2+ plus P(i). These data suggest that BHT and Ca2+ plus P(i) increase mitochondrial permeability via two mutually exclusive mechanisms.

Ca(2+)-triggered membrane permeability transition in deenergized mitochondria from rat liver

The opening of the cyclosporin A-sensitive permeability transition pore (MTP) in deenergized mitochondria was induced only at millimolar Ca2+. Pretreatment of the mitochondria with 'inducers', such as duroquinone and phenylarsine oxide, allowed observing the pore opening at 0.01-0.1 mM Ca2+. Duroquinone caused a rapid (within 20 s) NAD(P)H oxidation which was followed by a slow (20 min) induction of the pore sensitive to low Ca2+. Phenylarsine oxide capable of cross-linking of vicinal SH-groups caused pore formation without the oxidation of NAD(P)H. The pore opening by both 'inducers' was prevented by N-ethylmaleimide. We propose that oxidation or cross-linking of critical dithiol(s) in membrane proteins increase the sensitivity of a putative 'Ca(2+)-sensor' that regulates the permeability transition pore opening.

Gliotoxin stimulates Ca2+ release from intact rat liver mitochondria

Gliotoxin is an epidithiodioxopiperazine compound which can both react with sulfhydryl groups and form hydrogen peroxide. Rat liver mitochondria contain a prooxidant-regulated specific Ca2+ release pathway. Here we report that gliotoxin at low concentrations stimulates Ca2+ release via this pathway in isolated mitochondria. Ca2+ release is not promoted by gliotoxin exposed to disulfide-reducing reagents prior to addition to mitochondria or when its disulfide moiety is dimethylated. Gliotoxin is equally effective in glutathione-depleted and glutathione-adequate mitochondria. This and the unchanged mitochondrial oxygen consumption in the presence of gliotoxin suggest that the compound stimulates Ca2+ release by reacting with critical mitochondrial thiol compounds and not by increasing hydrogen peroxide formation in mitochondria. The gliotoxin-induced Ca2+ release is paralleled by hydrolysis of mitochondrial pyridine nucleotides, and both pyridine nucleotide hydrolysis and Ca2+ release are inhibited by cyclosporin A. These findings provide further insight into the regulation of Ca2+ release from intact mitochondria.

Phenylarsine oxide stimulates pyridine nucleotide-linked Ca2+ release from rat liver mitochondria

Rat liver mitochondria contain a specific Ca2+ release pathway which operates when oxidized mitochondrial pyridine nucleotides are hydrolysed to ADPribose and nicotinamide. Here we report that the hydrophobic bifunctional thiol reagent phenylarsine oxide (PhAsO) at low concentrations stimulates this pathway by promoting a Ca(2+)-dependent hydrolysis of oxidized mitochondrial pyridine nucleotides. Ca2+ release is inhibited by cyclosporine A or m-iodobenzylguanidine, compounds known to prevent intramitochondrial pyridine nucleotide hydrolysis or protein mono(ADPribosyl)ation, respectively. At higher concentrations, PhAsO causes non-specific leakiness of mitochondria.

Butylated hydroxytoluene prevents cumene hydroperoxide-induced Ca2+ release from liver mitochondria by inhibiting pyridine nucleotide hydrolysis

The mechanism by which the free radical scavenger butylated hydroxytoluene (BHT) prevents cumene hydroperoxide-induced Ca2+ release from rat liver mitochondria was studied. In Ca(2+)-loaded mitochondria cumene hydroperoxide induced a rapid oxidation and subsequent hydrolysis of the pyridine nucleotides. In the presence of BHT, pyridine nucleotide oxidation by cumene hydroperoxide occurred but was reversible as hydrolysis was prevented by BHT. However, the addition of BHT directly to rat liver submitochondrial particles did not inhibit NAD+ hydrolysis or the formation of ADP-ribose from NAD+. Thus, whilst BHT prevented NAD+ hydrolysis in isolated mitochondria, this appeared not to be due to a direct effect of BHT on the NADase. It is concluded that the mechanism of action of BHT on cumene hydroperoxide-induced Ca2+ release from mitochondria involves the inhibition of pyridine nucleotide hydrolysis by an indirect mechanism rather than the radical scavenging properties of BHT.

Why is inorganic phosphate necessary for uncoupling of oxidative phosphorylation by Cd2+ in rat liver mitochondria?

The phosphate (Pi)-dependent uncoupling action of Cd2+ in oxidative phosphorylation in rat liver mitochondria was studied mainly in terms of Pi transport. Cd2+ at 2 microM caused full uncoupling in the presence of 10 mM Pi, but no uncoupling in the absence of Pi. Cd2+ released state 4 respiration after a certain lag-time, and then the respiration increased progressively with time. After its addition, Cd2+ was taken up by mitochondria in a similar period to the lag time before respiratory release. KIH-201, a potent and specific inhibitor of Pi transport via the Pi/H+ symporter, abolished the uncoupling completely. Cd2+ caused dissipation of the electric transmembrane potential (delta psi) and swelling of mitochondria in a Pi-dependent manner. Uncoupling by Cd2+ was found to take place in parallel with the uptake of Pi into mitochondria via the Pi/H+ symporter, suggesting that the uncoupling was due to acceleration of H+ influx through the Pi/H+ symporter activated by Cd2+.

The role of lipid peroxidation products in cumene hydroperoxide-induced Ca2+ efflux from mitochondria

Cumene hydroperoxide-induced calcium release from mitochondria has been studied. Activation of lipid peroxidation by increasing concentrations of cumene hydroperoxide does not enhance calcium efflux induced by low (up to 50 microM) concentration of cumene hydroperoxide. It is concluded that cumene hydroperoxide-induced calcium release depends mainly on processes coupled to hydroperoxide reduction by an endogenous enzyme system.

Phenylarsine oxide induces the cyclosporin A-sensitive membrane permeability transition in rat liver mitochondria

This paper reports an investigation on the effects of the hydrophobic, bifunctional SH group reagent phenylarsine oxide (PhAsO) on mitochondrial membrane permeability. We show that PhAsO is a potent inducer of the mitochondrial permeability transition in a process which is sensitive to both the oxygen radical scavanger BHT and to cyclosporin A. The PhAsO-induced permeability transition is stimulated by Ca2+ but takes place also in the presence of EGTA in a process that maintains its sensitivity to BHT and cyclosporin A. Our findings suggest that, at variance from other known inducers of the permeability transition, PhAsO reacts directly with functional SH groups that are inaccessible to hydrophilic reagents in the absence of Ca2+.

Mechanism accounting for the induction of nonspecific permeability of the inner mitochondrial membrane by hydroperoxides

The effect of antioxidants on the nonspecific permeability of the inner mitochondrial membrane induced by cumene hydroperoxide or Ca(2+) has been studied. Butylated hydroxytoluene, butylated hydroxyanisole and 2,2,5,7,8-pentamethyl-6-chromanol, taken at a concentration up to 50 microM, suppress the cumene hydroperoxide-induced accumulation of lipid peroxidation products. In the same range of concentrations, these antioxidants inhibit the activation of nonspecific permeability by cumene hydroperoxide or Ca(2+). Propyl gallate, being less effective under such conditions, fails to affect the induction of nonspecific permeability. Additionally, 2,2,5,7,8-pentamethyl-6-chromanol at a concentration decreasing the accumulation of lipid peroxidation products by 70% has been shown not to increase the lag period of nonspecific permeability induction. Higher antioxidant concentrations, while leading to an increase in the lag period of nonspecific permeability induction, cause but minor suppression of lipid peroxidation. From the results obtained we can assume that free radicals formed in the course of hydroperoxide decomposition or on mitochondrial redox complex interact directly with a system responsible for nonspecific permeability or with regulating components of this system.

A comparison of phospholipid degradation by oxidation and hydrolysis during the mitochondrial permeability transition

The peroxidation and hydrolysis of mitochondrial phospholipids has been examined under conditions which are referable to induction of the permeability transition by t-butylhydroperoxide. Over a 30-min time course, the peroxide causes formation of 0.3 nmol/mg protein of malondialdehyde. This value is little effected by Ca2+, Sr2+, or Mn2+ but is increased approximately fivefold by Fe2+. The latter cation, but not the others, results in malondialdehyde formation in the absence of added peroxide. Partially oxidized phosphatidylethanolamine is present in normal mitochondria and is increased by approximately 50% following t-butylhydroperoxide treatment; however, the amounts observed are in the range of 0.4-0.6 mol% of total phosphatidylethanolamine. The minor degradation by peroxidation is in contrast to approximately 2.5 mol% degradation which occurs by hydrolysis. This degree of hydrolysis is accompanied by mitochondrial swelling and Mg2+ release, while a comparable level of peroxidation (malondialdehyde formation) is not. It is concluded that induction of the permeability transition by t-butylhydroperoxide does not represent damage to the membrane lipid phase caused by peroxidation. It is possible, however, that peroxidation accelerates the accumulation of phospholipid hydrolysis products and is thereby a factor which favors the transition.

A complex effect of arsenite on the formation of alpha-ketoglutarate in rat liver mitochondria

This investigation presents disturbances of the mitochondrial metabolism by arsenite, a hydrophilic dithiol reagent known as an inhibitor of mitochondrial alpha-keto acid dehydrogenases. Arsenite at concentrations of 0.1-1.0 mM was shown to induce a considerable oxidation of intramitochondrial NADPH, NADH, and glutathione without decreasing the mitochondrial membrane potential. The oxidation of NAD(P)H required the presence of phosphate and was sensitive to ruthenium red, but occurred without the addition of calcium salts. Mitochondrial reactions producing alpha-ketoglutarate from glutamate and isocitrate were modulated by arsenite through various mechanisms: (i) both glutamate transaminations, with oxaloacetate and with pyruvate, were inhibited by accumulating alpha-ketoglutarate; however, at low concentrations of alpha-ketoglutarate the aspartate aminotransferase reaction was stimulated due to the increase of NAD+ content; (ii) the oxidation of isocitrate was stimulated at its low concentration only, due to the oxidation of NADPH and NADH; this oxidation was prevented by concentrations of citrate or isocitrate greater than 1 mM; (iii) the conversion of isocitrate to citrate was suppressed, presumably as a result of the decrease of Mg2+ concentration in mitochondria. Thus the depletion of mitochondrial vicinal thiol groups in hydrophilic domains disturbs the mitochondrial metabolism not only by the inhibition of alpha-keto acid dehydrogenases but also by the oxidation of NAD(P)H and, possibly, by the change in the ion concentrations.

The mitochondrial aspartate/glutamate and ADP/ATP carrier switch from obligate counterexchange to unidirectional transport after modification by SH-reagents

The influence of various SH-reagents on the aspartate/glutamate carrier was investigated in the reconstituted system. When liposomes carrying partially purified carrier protein were treated with 5,5'-dithiobis(2-nitrobenzoic acid) or N-ethylmaleimide, antiport activity was strongly reduced. Several mercury compounds exerted a dual effect. They completely blocked the antiport and, in addition, induced an efflux pathway for internal aspartate. The maximum rate of this unidirectional flux was comparable to the original antiport activity. Induction of efflux always was coupled to inhibition of antiport. Efflux was neither due to unspecific leakage of proteoliposomes nor to a possible contamination by porin, but depended on active carrier protein, as elucidated by the sensitivity to proteinases and protein-modifying reagents. Besides efflux of aspartate, HgCl2 and mersalyl also induced a slow efflux of ATP from liposomes carrying coreconstituted aspartate/glutamate and ADP/ATP carrier. The two efflux activities could be discriminated taking advantage of the differential effectiveness of several inhibitors and proteinases. Although basic carrier properties were changed by the applied mercurials (Dierks, T., Salentin, A. and Krämer, R. (1990) Biochim. Biophys. Acta 1028, 281), aspartate and ATP efflux could clearly be correlated with the aspartate/glutamate and the ADP/ATP carrier, respectively. When purifying these two translocators the respective efflux activity copurified with the antiporter, thus elucidating that the two different transport functions are mediated by the same protein. These results argue for a participation of the aspartate/glutamate and the ADP/ATP carrier in the generally observed increase of mitochondrial permeability after treatment with SH-reagents.

Mechanism of nitrofurantoin toxicity and oxidative stress in mitochondria

5-Nitrofuran derivatives change the inner mitochondrial membrane permeability as indicated by the transmembrane potential, the rate of spontaneous K+ efflux and the basal respiratory rate: (a) at low concentrations nitrofurantoin prevents the increase of inner membrane permeability due to hydroperoxides or to diamide; (b) at higher concentrations or after longer times of incubation, nitrofurantoin enhances the membrane damage due to hydroperoxides or to diamide; the damage due Ca2+ plus Pi is enhanced by nitrofurantoin at all concentrations; (c) higher nitrofurantoin concentrations cause membrane damage independently of the presence of hydroperoxides or of diamide. The effect of nitrofurantoin is cancelled by the addition of free-radical scavengers. The above effects of nitrofurantoin are compatible with the observations of Mason and colleagues that nitrofurantoin is reduced by a NADPH nitroreductase to a nitro anion radical which can then undergo subsequent reactions, among which are (a) initiation of a free-radical reaction chain and (b) reduction of hydroperoxides and diamide.

Permeability of inner mitochondrial membrane and oxidative stress

The mechanism of increase in the inner membrane permeability induced by Ca2+ plus Pi, diamide and hydroperoxides has been analyzed. (1) The permeability increase is antagonized by oligomycin and favoured by atractyloside. The promoting effect of atractyloside is strongly reduced if the mitochondria are simultaneously treated with oligomycin. (2) Addition of the free-radical scavenger, butylhydroxytoluene, results in a complete protection of the membrane with respect to the permeability increase. (3) Although membrane damage and depression of the GSH concentration are often associated, there is no direct correlation between extent of membrane damage and concentration of reduced glutathione. Abolition of the permeability increase by butylhydroxytoluene or by oligomycin is not accompanied by maintenance of a high GSH concentration in the presence of diamide or hydroperoxides. The membrane damage induced by Ca2+ plus Pi is not accompanied by a depression of the GSH concentration. (4) It is proposed that a variety of processes causing an increased permeability of the inner mitochondrial membrane merge into some ultimate common steps involving the action of oxygen radicals.