The role of low (< or = 1 mM) phosphate concentrations in regulation of mitochondrial permeability: modulation of matrix free Ca2+ concentration

Under a variety of conditions, the permeability of the inner mitochondrial membrane to small solutes can be nonselectively increased. A classic mitochondrial permeability transition (MPT) was originally identified based on its dependence on matrix Ca2+ and its extreme sensitivity to cyclosporin A (CsA). It is now clear, however, that several additional and distinct processes can also produce increases in mitochondrial permeability. Both mitochondrial signal peptides (P. M. Sokolove and K. W. Kinnally, 1996, Arch. Biochem. Biophys. 336, 69-76) and butylated hydroxytoluene (BHT) (P. M. Sokolove and L. M. Haley, 1996, J. Bioenerg. Biomembr. 28, 199-206), for example, induce permeability increases that are relatively CsA insensitive and that persist in the presence of EGTA. Inorganic phosphate (Pi) appears to play a key role in each of these permeability increases. High (>1 mM) Pi levels facilitate the classic MPT, while Pi concentrations below 1 mM stimulate the permeability increase induced by signal peptides and inhibit that triggered by BHT. The effect of high Pi concentrations can most probably be explained by exchange of the anion for matrix ADP and the resulting alleviation of ADP-mediated inhibition of the MPT (R. G. Lapidus and P. M. Sokolove, 1994, J. Biol. Chem. 269, 18931-18936). In the experiments reported here, the mechanisms underlying the effects of low Pi concentrations on mitochondrial permeability were investigated, by monitoring mitochondrial volume, with the following results: (1) A hitherto unrecognized ability of Pi (<1 mM) to increase the lag preceding induction of the classic MPT by diamide, phenylarsine oxide, and t-butylhydroperoxide was identified. (2) Data were obtained suggesting that all of the effects of low Pi concentration, stimulation of signal peptide-induced swelling, blockade of BHT-induced swelling, and delay of the classic MPT, can be attributed to the capacity of the anion to complex Ca2+ in the mitochondrial matrix. (3) Differences in the responses of these three systems for enhancing mitochondrial permeability to experimental manipulation indicate that matrix Ca2+ plays more than one role in the regulation of mitochondrial permeability. An additional important finding is the observation that failure of EGTA to alter a mitochondrial process need not mean that the process is Ca2+ independent. In a multicompartment system, absence of EGTA action may instead reflect failure of the chelator to gain access to regulatory Ca2+.     

Free fatty acid effects on mitochondrial permeability: an overview

A variety of experimental conditions elicit increases in mitochondrial permeability that can be differentiated from the classic cyclosporin A (CsA)-sensitive mitochondrial permeability transition (MPT). For example, butylated hydroxytoluene, signal peptides, and the hormone thyroxine have been shown to promote increases in mitochondrial permeability that are CsA-insensitive. Our laboratory has recently demonstrated that palmitic acid, a saturated 16-carbon free fatty acid (FFA), can also open a CsA-insensitive pore. This nonclassic permeability transition (NCPT) is further distinguished by a nonselective dependence on divalent cations and by spontaneous closure. To determine if induction of the NCPT is specific to palmitic acid and to resolve conflicting reports as to the mechanisms by which FFAs alter mitochondrial permeability, we examined in detail mitochondrial swelling induced by FFAs that differ in chain length and degree of saturation. The following results were obtained: (1) In the presence of modest Ca2+ concentrations (75 nmol/mg protein), medium-chain FFAs (C12-C18) were more effective in eliciting mitochondrial swelling than were shorter or longer FFAs; medium-chain alkanols and amines had no effect. (2) Under these conditions, saturated FFAs induced CsA-insensitive swelling with all the characteristics of the NCPT, while unsaturated FFAs triggered the MPT. (3) When matrix Ca2+ concentration was further elevated, unsaturated FFAs triggered the NCPT. (4) Mitochondrial swelling induced by saturated FFAs was inhibited by unsaturated FFAs but not by other saturated FFAs or medium-chain alkanols. These results suggest that ambient conditions can greatly influence the nature of the increase in mitochondrial permeability induced by FFAs. They are also consistent with our earlier proposal that Ca2+ (or Sr2+) binding to FFAs in the inner leaflet of the inner mitochondrial membrane underlies the NCPT.     

Functional consequences of the sustained or transient activation by Bax of the mitochondrial permeability transition pore.

The overexpression of Bax kills cells by a mechanism that depends on induction of the mitochondrial permeability transition (MPT) (Pastorino, J. G., Chen, S.-T., Tafani, M., Snyder, J. W., and Farber, J. L. (1998) J. Biol. Chem. 273, 7770-7775). In the present study, purified, recombinant Bax opened the mitochondrial permeability transition pore (PTP). Depending on its concentration, Bax had two distinct effects. At a concentration of 125 nM, Bax caused the release of the intermembranous proteins cytochrome c and adenylate kinase and the release from the matrix of sequestered calcein, effects prevented by the inhibitor of the PTP cyclosporin A (CSA). At this concentration of Bax, there was no detectable mitochondrial swelling or depolarization. These effects of low Bax concentrations are interpreted as the consequence of transient, non-synchronous activation of the PTP followed by a prompt recovery of mitochondrial integrity. By contrast, Bax concentrations between 250 nM and 1 microM caused a sustained opening of the PTP with consequent persistent mitochondrial swelling and deenergization (the MPT). CSA prevented the MPT induced by Bax. Increasing concentrations of calcium caused a greater proportion of the mitochondria to undergo the MPT in the presence of Bax. Importantly, two known mediators of apoptosis, ceramide and GD3 ganglioside, potentiated the induction by Bax of the MPT. The data imply that Bax mediates the opening of the mitochondrial PTP with the resultant release of cytochrome c from the intermembranous space.     

Induction of a non-specific permeability transition in mitochondria from Yarrowia lipolytica and Dipodascus (Endomyces) magnusii yeasts

In this study we used tightly-coupled mitochondria from Yarrowia lipolytica and Dipodascus (Endomyces) magnusii yeasts, possessing a respiratory chain with the usual three points of energy conservation. High-amplitude swelling and collapse of the membrane potential were used as parameters for demonstrating induction of the mitochondrial permeability transition due to opening of a pore (mPTP). Mitochondria from Y. lipolytica, lacking a natural mitochondrial Ca²⁺ uptake pathway, and from D. magnusii, harboring a high-capacitive, regulated mitochondrial Ca²⁺ transport system (Bazhenova et al. J Biol Chem 273:4372–4377, 1998a; Bazhenova et al. Biochim Biophys Acta 1371:96–100, 1998b; Deryabina and Zvyagilskaya Biochemistry (Moscow) 65:1352–1356, 2000; Deryabina et al. J Biol Chem 276:47801–47806, 2001) were very resistant to Ca²⁺ overload. However, exposure of yeast mitochondria to 50–100 μM Ca²⁺ in the presence of the Ca²⁺ ionophore ETH129 induced collapse of the membrane potential, possibly due to activation of the fatty acid-dependent Ca²⁺/nH⁺-antiporter, with no classical mPTP induction. The absence of response in yeast mitochondria was not simply due to structural limitations, since large-amplitude swelling occurred in the presence of alamethicin, a hydrophobic, helical peptide, forming voltage-sensitive ion channels in lipid membranes. Ca²⁺- ETH129-induced activation of the Ca²⁺/H⁺-antiport system was inhibited and prevented by bovine serum albumin, and partially by inorganic phosphate and ATP. We subjected yeast mitochondria to other conditions known to induce the permeability transition in animal mitochondria, i.e., Ca²⁺ overload (in the presence of ETH129) combined with palmitic acid (Mironova et al. J Bioenerg Biomembr 33:319–331, 2001; Sultan and Sokolove Arch Biochem Biophys 386:37–51, 2001), SH-reagents, carboxyatractyloside (an inhibitor of the ADP/ATP translocator), depletion of intramitochondrial adenine nucleotide pools, deenergization of mitochondria, and shifting to acidic pH values in the presence of high phosphate concentrations. None of the above-mentioned substances or conditions induced a mPTP-like pore. It is thus evident that the permeability transition in yeast mitochondria is not coupled with Ca²⁺ uptake and is differently regulated compared to the mPTP of animal mitochondria.     

Mitochondrial swelling and cytochrome c release: sensitivity to cyclosporin A and calcium

The opening of mitochondrial membrane permeability transition (MPT) pores, which results in a cyclosporin A (CsA)-sensitive and Ca(2+)-dependent dissipation of the membrane potential (delta psi) and swelling (classical MPT), has been postulated to play an important role in the release of cytochrome c (Cyt.c) and also in apoptotic cell death. Recently, it has been reported that CsA-insensitive or Ca(2+)-independent MPT can be classified as non-classic MPT. Therefore, we studied the effects of apoptosis-inducing agents on mitochondrial functions with respect to their CsA-sensitivity and Ca(2+)-dependency. CsA-sensitive mitochondrial swelling, depolarization, and the release of Ca2+ and Cyt.c were induced by low concentrations of arachidonic acid, triiodothyronine (T3), or 6-hydroxdopamine but not by valinomycin and high concentrations of the fatty acid or T3. Fe2+/ADP and 2,2,-azobis-(2-amidinopropane) dihydrochloride (AAPH) induced swelling of mitochondria and the release of Ca2+ and Cyt.c were not coupled with depolarization or CsA-sensitivity while dibucaine-induced swelling occurred without depolarization, Cyt.c-release or by a CsA-sensitive mechanism. A protonophoric FCCP and SF-6847 induced depolarization and Ca(2+)-release occurred in a CsA-insensitive manner and failed to stimulate the release of Cyt.c. These results indicate that ambient conditions of mitochondria can greatly influence the state of membrane stability and that Cyt.c release may occur not only via a CsA-sensitive MPT but also by way of a CsA-insensitive membrane deterioration.     

Mitochondrial injury by disulfiram: two different mechanisms of the mitochondrial permeability transition.

Disulfiram (Ds), a clinically employed alcohol deterrent of the thiuram disulfide (TD) class of compounds, is known to cause hepatitis and neuropathies. Although this drug has been shown to inhibit different thiol-containing enzymes, the actual mechanism of Ds toxicity is not clear. We have previously demonstrated that Ds impairs the permeability of inner mitochondrial membrane (IMM) [Arch. Biochem. Biophys. 356 (1998) 46]. In this report, the effect of Ds and its structural analogue thiram (Th) on mitochondrial functions was studied in detail. We found that mitochondria metabolize TDs in a NAD(P)H- and GSH-dependent manner. At the concentration above characteristic threshold, TDs induced irreversible oxidation of NAD(P)H and glutathione (GSH) pools, collapse of transmembrane potential, and inhibition of oxidative phosphorylation. The presence of Ca(2+) and exhaustion of mitochondrial glutathione (GSH+GSSG) decreased the threshold concentration of TDs. Swelling of the mitochondria and leakage of non-transported fluorescent dye BCECF from the matrix indicated that TDs induced the mitochondrial permeability transition (MPT). Mitochondrial permeabilization by TDs involves two, apparently distinct mechanisms. In the presence of Ca(2+), TDs produced cylosporin A-sensitive swelling of mitochondria, which was inhibited by ADP and accelerated by carboxyatractyloside (CATR) and phosphate. In contrast, the swelling produced by TDs in the absence of Ca(2+) was not sensitive to cyclosporin A (CsA), ADP and CATR but was inhibited by phosphate. Titration with N-ethylmaleimide revealed that these two mechanisms involve different SH-groups and probably different transport proteins on the IMM. Our findings indicate that at pharmacologically relevant concentrations TDs may cause an irreversible mitochondrial injury as a result of induction of the MPT.     

Phosphorylation of a peptide related to subunit c of the F0F1-ATPase/ATP synthase and relationship to permeability transition pore opening in mitochondria

A phosphorylated polypeptide (ScIRP) from the inner membrane of rat liver mitochondria with an apparent molecular mass of 3.5 kDa was found to be immunoreactive with specific antibodies against subunit c of F₀F₁-ATPase/ATP synthase (Azarashvily, T. S., Tyynelä, J., Baumann, M., Evtodienko, Yu. V., and Saris, N.-E. L. (2000). Biochem. Biophys. Res. Commun. 270, 741–744. In the present paper we show that the dephosphorylation of ScIRP was promoted by the Ca²⁺-induced mitochondrial permeability transition (MPT) and prevented by cyclosporin A. Preincubation of ScIRP isolated in its dephosphorylated form with the mitochondrial suspension decreased the membrane potential (_M) and the Ca²⁺-uptake capacity by promoting MPT. Incorporation of ScIRP into black-lipid membranes increased the membrane conductivity by inducing channel formation that was also suppressed by antibodies to subunit c. These data indicate that the phosphorylation level of ScIRP is influenced by the MPT pore state, presumably by stimulation of calcineurin phosphatase by the Ca²⁺ used to induce MPT. The possibility of ScIRP being part of the MPT pore assembly is discussed in view of its capability to induced channel activity.     

Tributyltin causes cytochrome C release from isolated mitochondria by two discrete mechanisms

Using isolated liver mitochondria we show that low concentrations of TBT (0.5 microM) cause the release of mitochondrial cytochrome c, in the presence of Ca(2+). This is reflected in a rapid loss of membrane potential (DeltaPsi(m)), and a large-amplitude swelling characteristic of mitochondrial permeability transition (MPT). Despite this, the inclusion of cyclosporin A could not prevent the release of cytochrome c. Further, in the absence of Ca(2+), low concentrations of TBT (0.5 microM) resulted in a slow sub-maximal shift of DeltaPsi(m), not characteristic of MPT, which was still paralleled by a release of cytochrome c. Further experiments showed that the loss of DeltaPsi(m) in the absence of Ca(2+) was due to a combination of inhibition of respiration and a direct uncoupling effect on the respiratory chain. Under these conditions, rapid swelling of mitochondria could be demonstrated, due to chloride exchange over the inner mitochondrial membrane. Taken together these data suggest that TBT can induce the release of cytochrome c in intact cells by at least two mechanisms. The first and critical mechanism is initiated immediately the mitochondria sense the presence of TBT and involves a slow loss of DeltaPsi(m) and induction of swelling, which allows release of cytochrome c in a relatively non-specific manner and independently from a rise in [Ca(2+)](i). The second mechanism involves the induction of formal MPT as intracellular [Ca(2+)](i) increases. These data help to explain previous observations in intact lymphocytes demonstrating TBT-induced release of mitochondrial cytochrome c in the absence of a rise in [Ca(2+)](i) (Stridh, H., Gigliotti, D., Orrenius, S., and Cotgreave, I. A. (1999) Biochem. Biophys. Res. Commun. 266, 460-465).     

The role of formylmethanofuran: tetrahydromethanopterin formyltransferase in methanogenesis from carbon dioxide

Formylmethanofuran: tetrahydromethanopterin formyltransferase was purified to electrophoretic homogeneity from cells of Methanobacterium thermoautotrophicum. The enzyme is a tetramer of similar or identical subunits (Mr = 41,000). The equilibrium favors transfer of the formyl group to tetrahydromethanopterin (H4MPT) at physiological pH. The product of formyl transfer by the purified enzyme was shown by a number of criteria to be 5-formyl-H4MPT, as opposed to 10-formyl-H4MPT or 5,10-methenyl-H4MPT. Reconstitution of a portion of the methanogenic C1 cycle was effected by combining purified formyltransferase, methenyl-H4MPT cyclohydrolase, formylmethanofuran, and H4MPT to give methenyl-H4MPT. Additional reconstitution experiments established that the formyltransferase is an essential enzyme for the conversion of carbon dioxide to methane. In conjunction with previously published data (Donnelly, M.I., Escalante-Semerena, J.C., Rinehart, K. L., Jr., and Wolfe, R.S. (1985) Arch. Biochem. Biophys. 242, 430-439), these data substantiate the role of 5-formyl-H4MPT as an intermediate of methanogenesis.     

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

Mitochondria undergo a permeability transition (PT), 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 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 bestimulated 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.     

Prooxidants open both the mitochondrial permeability transition pore and a low-conductance channel in the inner mitochondrial membrane

Mitochondria can be induced by a variety of agents/conditions to undergo a permeability transition (MPT), which nonselectively increases the permeability of the inner membrane (i.m.) to small (<1500 Da) solutes. Prooxidants are generally considered to trigger the MPT, but some investigators suggest instead that prooxidants open a Ca(2+)-selective channel in the inner mitochondrial membrane and that the opening of this channel, when coupled with Ca(2+) cycling mediated by the Ca(2+) uniporter, leads ultimately to the observed increase in mitochondrial permeability [see, e.g., Schlegel et al. (1992) Biochem. J. 285, 65]. S. A. Novgorodov and T. I. Gudz [J. Bioenerg. Biomembr. (1996) 28, 139] propose that the i.m. contains a pore that, upon exposure to prooxidants, can open to two states, one of which conducts only H(+) and one of which is the classic MPT pore. Given the current interest in increased mitochondrial permeability as a factor in apoptotic cell death, it is important to determine whether i.m. permeability is regulated in one or multiple ways and, in the latter event, to characterize each regulatory mechanism in detail. This study examined the effects of the prooxidants diamide and t-butylhydroperoxide (t-BuOOH) on the permeability of isolated rat liver mitochondria. Under the experimental conditions used, t-BuOOH induced mitochondrial swelling only in the presence of exogenous Ca(2+) (>2 microM), whereas diamide was effective in its absence. In the absence of exogenous inorganic phosphate (P(i)), (1) both prooxidants caused a collapse of the membrane potential (DeltaPsi) that preceded the onset of mitochondrial swelling; (2) cyclosporin A eliminated the swelling induced by diamide and dramatically slowed that elicited by t-BuOOH, without altering prooxidant-induced depolarization; (3) collapse of DeltaPsi was associated with Ca(2+) efflux but not with efflux of glutathione; (4) neither Ca(2+) efflux nor DeltaPsi collapse was sensitive to ruthenium red; (5) collapse of DeltaPsi was accompanied by an increase in matrix pH; no stimulation of respiration was observed; (6) Sr(2+) was able to substitute for Ca(2+) in supporting t-BuOOH-induced i.m. depolarization, but not swelling; (7) in addition to being insensitive to CsA, the collapse of DeltaPsi was also resistant to trifluoperazine, spermine, and Mg(2+), all of which block the MPT; and (8) DeltaPsi was restored (and its collapse was inhibited) upon addition of dithiothreitol, ADP, ATP or EGTA. We suggest that these results indicate that prooxidants open two channels in the i.m.: the classic MPT and a low-conductance channel with clearly distinct properties. Opening of the low-conductance channel requires sulfhydryl group oxidation and the presence of a divalent cation; both Ca(2+) and Sr(2+) are effective. The channel permits the passage of cations, including Ca(2+), but not of protons. It is insensitive to inhibitors of the classic MPT.     

Lithocholic acid induces two different calcium-dependent inner membrane permeability systems in liver mitochondria

The effect of the most hydrophobic bile acid–lithocholic–as an inducer of two different Ca²⁺-dependent inner membrane permeability systems was studied on isolated rat liver mitochondria. It is shown that the addition of lithocholic acid at a concentration of 20 μM to the Ca²⁺-loaded mitochondria leads to swelling of the organelles, rapid release of Ca²⁺ from the matrix and almost complete collapse of Δψ. Mitochondrial pore blocker cyclosporin A (CsA) eliminates mitochondrial swelling but has no effect on the process of Ca²⁺ release and Δψ collapse. In the absence of Ca²⁺ lithocholic acid causes only a transient decrease of Δψ with subsequent complete recovery. Ruthenium red, inhibitor of mitochondrial Ca²⁺ uniporter, which blocks Ca²⁺ influx into the matrix, prevents mitochondrial swelling induced by lithocholic acid. At the same time, ruthenium red, which is added before lithocholic acid to the Ca²⁺-preloaded mitochondria, does not affect the swelling of the organelles but reduces the CsA-insensitive drop in Δψ. It is concluded that lithocholic acid is able to induce two Ca²⁺-dependent energy dissipation systems in the inner membrane of liver mitochondria: CsA-sensitive mitochondrial pore and CsA-insensitive permeability, which exhibits sensitivity to ruthenium red. It is found that the effect of this bile acid as an inductor of CsA-sensitive mitochondrial pore is not associated with the modulation of Pi effects. It is assumed that CsA-insensitive action of lithocholic acid is associated with the induction of Ca²⁺ efflux from the matrix in exchange for protons. In this case, the energy-dependent Ca²⁺ transport in the opposite direction with the participation of mitochondrial calcium uniporter sensitive to ruthenium red leads to the formation of calcium cycle and thereby to energy dissipation.     

The permeability transition in heart mitochondria is regulated synergistically by ADP and cyclosporin A.

Heart mitochondria respiring in a sucrose medium containing P(i) show a permeability transition when challenged with Ca2+ and an oxidant such as cumene hydroperoxide. The transition results from the opening of a Ca(2+)-dependent pore and is evidenced by loss of membrane potential (delta psi) and osmotic swelling due to uptake of sucrose and other solutes. In the absence of oxidant, high concentrations of Ca2+ (100-150 microM) are necessary to induce loss of delta psi and initiate swelling. Cyclosporin A delays the loss of delta psi but enhances swelling under these conditions, apparently by promoting better retention of accumulated Ca2+. Cyclosporin A and ADP together restore delta psi in respiring mitochondria that have undergone the permeability transition at levels that are not effective when either is added alone. When the state of the Ca(2+)-dependent pore is assessed using passive osmotic contraction in response to polyethylene glycol (Haworth, R. A., and Hunter, D. R. (1979) Arch. Biochem. Biophys. 195, 460-467), cyclosporin A is found to be a partial inhibitor of solute flow through the open pore. Cyclosporin A decreases the Vmax of passive contraction and increases the Km for Ca2+ without affecting the Hill slope. ADP in the presence of carboxyatractyloside closes the pore almost completely even in the presence of 40 microM Ca2+. ADP shows mixed type inhibition of the Ca(2+)-dependent pore, and cyclosporin A increases the affinity of the pore for ADP. It is concluded that cyclosporin A and ADP act synergistically to close the Ca(2+)-dependent pore of the mitochondrion and that the pore is probably not formed directly from the adenine nucleotide transporter.     

Factors affecting oxygen-induced changes in the activity of CTP-dependent lipid kinases in yeast

Previous work from this Laboratory (Szkopińska et al., 1988, Arch. Biochem. Biophys., 266, 124-131) indicated that CTP is a phosphate donor for the synthesis of phosphatidic acid and dolichyl phosphates. The elucidation of the role of mitochondrial membranes and mitochondrial proteins (isolation of rho- mutant) as well as specific detergents and sterols has been the aim of this work.     

Cyclosporin A binding in mitochondrial cyclophilin inhibits the permeability transition pore and protects hearts from ischaemia/reperfusion injury

When loaded with high (pathological) levels of Ca²⁺, mitochondria become swollen and uncoupled as the result of a large non-specific increase in membrane permeability. This process, known as the mitochondrial permeability transition (MPT), is exacerbated by oxidative stress and adenine nucleotide depletion. These conditions match those that a heart experiences during reperfusion following a period of ischaemia. The MPT is caused by the opening of a non-specific pore that can be prevented by sub-micromolar concentrations of cyclosporin A (CsA). A variety of conditions that increase the sensitivity of pore opening to [Ca²⁺], such as thiol modification, oxidative stress, increased matrix volume and chaotropic agents, all enhance the binding of matrix cyclophilin (CyP) to the inner mitochondrial membrane in a CsA-sensitive manner. In contrast, ADP, membrane potential and low pH decrease the sensitivity of pore opening to [Ca²⁺] without affecting CyP binding. We present a model of pore opening involving CyP binding to a membrane target protein followed by Ca²⁺-dependent triggering of a conformational change to induce channel opening. Using the ischaemic/reperfused rat heart we have shown that the mitochondrial pore does not open during ischaemia, but does do so during reperfusion. Recovery of heart during reperfusion is improved in the presence of 0.2 µM CsA, suggesting that the MPT may be critical in the transition from reversible to irreversible reperfusion injury. (Mol Cell Biochem 174: 167–172, 1997)     

Possible Mechanism for Formation and Regulation of the Palmitate-Induced Cyclosporin A-Insensitive Mitochondrial Pore

The mechanism of the palmitate-induced opening of the mitochondrial Ca2+-dependent cyclosporin A (CsA)-insensitive pore was studied, as well as the influence on this process of well-known modulators of the CsA-sensitive Ca2+-dependent pore. Palmitic acid, which can bind Ca2+ with high affinity, induced the cyclosporin A-insensitive swelling of mitochondria, whereas palmitoleic and 2-bromopalmitic acids, which have no such affinity for Ca2+, failed to induce the pore opening. The palmitate-induced Ca2+-dependent swelling of mitochondria was not affected by a well-known inhibitor of the CsA-sensitive pore (ADP) and an activator of this pore (inorganic phosphate, P(i)). However, this swelling was inhibited by physiological concentrations of ATP ([I]50 = 1.3 mM), but 100 microM ATP increased by 30% the rate of mitochondria swelling if Ca2+ had been added earlier. The effects of ATP (inhibition and activation) manifested themselves from different sides of the inner mitochondrial membrane. Mg2+ inhibited the palmitate-induced Ca2+-dependent swelling of mitochondria with [I]50 = 0.8 mM. It is concluded that palmitic acid induces the opening of the CsA-insensitive pore due to its ability for complexing with Ca2+. A possible mechanism of the pore formation and the influence of some modulators on this process are discussed.     

Ursodeoxycholic acid,in contrast to other bile acids,induces Ca<Superscript>2+</Superscript>-dependent cyclosporin A-insensitive permeability transition in liver mitochondria in the presence of potassium chloride

The effects of hydrophobic and hydrophilic bile acids as inducers of Ca²⁺-dependent permeability of the inner membrane were studied on isolated liver mitochondria. It is shown that in the absence of the inorganic phosphate (P_i)–a modulator of the mitochondrial pore–hydrophobic bile acids (lithocholic, deoxycholic, chenodeoxycholic) at concentrations of 20–50 μM, as well as a hydrophilic cholic acid at a concentration of 800 μM, induce swelling of liver mitochondria loaded with Ca²⁺. This effect is completely eliminated by a specific inhibitor of mitochondrial pore cyclosporin A (CsA). The effect of the bile acids as inducers of Ca²⁺-dependent CsA-sensitive mitochondrial pore is not associated with the modulation of the P_i effects. In contrast to other tested bile acids, a hydrophilic ursodeoxycholic acid (UDCA) at a concentration of 400 μM is able to induce Ca²⁺-dependent CsA-sensitive pore opening in liver mitochondria only in the presence of P_i or in the absence of potassium chloride in the incubation medium. In the presence of potassium chloride but in the absence of P_i, UDCA effects associated with the induction of the inner membrane permeability (swelling of mitochondria, drop in Δψ, and Ca²⁺ release from the matrix) are also observed in the presence of CsA. This Ca²⁺-dependent permeability of the inner membrane, in contrast to the “classical” CsA-sensitive pore, is characterized by a lower intensity of the mitochondrial swelling, a total drop in Δψ, and Ca²⁺ release from the matrix and is blocked by P_i. We suggest that the induction of the CsA-insensitive permeability in the inner mitochondrial membrane by UDCA is associated with activation of electrophoretic influx of K⁺ into the matrix and Ca²⁺ release from the matrix in exchange to H+. The effect of P_i as a blocker of such permeability is discussed.     

Commitment to apoptosis by GD3 ganglioside depends on opening of the mitochondrial permeability transition pore.

We have studied the effects of GD3 ganglioside on mitochondrial function in isolated mitochondria and intact cells. In isolated mitochondria, GD3 ganglioside induces complex changes of respiration that depend on the substrate being oxidized. However, these effects are secondary to opening of the cyclosporin A-sensitive permeability transition pore and to the ensuing swelling and cytochrome c depletion rather than to an interaction with the respiratory chain complexes. By using a novel in situ assay based on the fluorescence changes of mitochondrially entrapped calcein (Petronilli, V., Miotto, G., Canton, M., Colonna, R., Bernardi, P., and Di Lisa, F. (1999) Biophys. J. 76, 725-734), we unequivocally show that GD3 ganglioside also induces the mitochondrial permeability transition in intact cells and that this event precedes apoptosis. The mitochondrial effects of GD3 ganglioside are selective, in that they cannot be mimicked by either GD1a or GM3 gangliosides, and they are fully sensitive to cyclosporin A, which inhibits both the mitochondrial permeability transition in situ and the onset of apoptosis induced by GD3 ganglioside. These results provide compelling evidence that opening of the permeability transition pore is causally related to apoptosis.     

Mitochondrial membrane permeability transition and cell death

Mitochondria are important organelles for energy production, Ca2+ homeostasis, and cell death. In recent years, the role of the mitochondria in both apoptotic and necrotic cell death has received much attention. In apoptotic and necrotic death, an increase of mitochondrial membrane permeability is considered to be one of the key events, although the detailed mechanism remains to be elucidated. The mitochondrial membrane permeability transition (MPT) is a Ca2+-dependent increase in the permeability of the mitochondrial membrane that leads to loss of Deltapsi, mitochondrial swelling, and rupture of the outer mitochondrial membrane. The MPT is thought to occur after the opening of a channel, which is termed the permeability transition pore (PTP) and putatively consists of the voltage-dependent anion channel (VDAC), the adenine nucleotide translocator (ANT), cyclophilin D (Cyp D: a mitochondrial peptidyl prolyl-cis, trans-isomerase), and other molecule(s). Our studies of mice lacking Cyp D have revealed that it is essential for occurrence of the MPT and that the Cyp D-dependent MPT regulates some forms of necrotic cell death, but not apoptotic death. We have also shown that two anti-apoptotic proteins, Bcl-2 and Bcl-x(L), block the MPT by directly inhibition of VDAC activity. Here we summarize a role of the MPT in cell death.     

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.