Generation of the mitochondrial permeability transition does not involve inhibition of lysophospholipid acylation. Acyl-coenzyme A:1-acyllysophospholipid acyltransferase activity is not found in rat liver mitochondria

The mitochondrial permeability transition: Recent progress and open questions

Major progress has been made in defining the basis of the mitochondrial permeability transition, a Ca²⁺ -dependent permeability increase of the inner membrane that has puzzled mitochondrial research for almost 70 years. Initially considered an artefact of limited biological interest by most, over the years the permeability transition has raised to the status of regulator of mitochondrial ion homeostasis and of druggable effector mechanism of cell death. The permeability transition is mediated by opening of channel(s) modulated by matrix cyclophilin D, the permeability transition pore(s) (PTP). The field has received new impulse (a) from the hypothesis that the PTP may originate from a Ca²⁺ -dependent conformational change of F-ATP synthase and (b) from the reevaluation of the long-standing hypothesis that it originates from the adenine nucleotide translocator (ANT). Here, we provide a synthetic account of the structure of ANT and F-ATP synthase to discuss potential and controversial mechanisms through which they may form high-conductance channels; and review some intriguing findings from the wealth of early studies of PTP modulation that still await an explanation. We hope that this review will stimulate new experiments addressing the many outstanding problems, and thus contribute to the eventual solution of the puzzle of the permeability transition.

Mitochondrial calcium transport and the redox nature of the calcium-induced membrane permeability transition

Mitochondria possess a Ca²⁺ transport system composed of separate Ca²⁺ influx and efflux pathways. Intramitochondrial Ca²⁺ concentrations regulate oxidative phosphorylation, required for cell function and survival, and mitochondrial redox balance, that participates in a myriad of signaling and damaging pathways. The interaction between Ca²⁺ accumulation and redox imbalance regulates opening and closing of a highly regulated inner membrane pore, the membrane permeability transition pore (PTP). In this review, we discuss the regulation of the PTP by mitochondrial oxidants, reactive nitrogen species, and the interactions between these species and other PTP inducers. In addition, we discuss the involvement of mitochondrial redox imbalance and PTP in metabolic conditions such as atherogenesis, diabetes, obesity and in mtDNA stability.

Pore formation and uncoupling initiate a Ca2+-independent degradation of mitochondrial phospholipids

Mitochondria contain a type IIA secretory phospholipase A(2) that has been thought to hydrolyze phospholipids following Ca(2+) accumulation and induction of the permeability transition. These enzymes normally require millimolar Ca(2+) for optimal activity; however, no dependence of the mitochondrial activity on Ca(2+) can be demonstrated upon equilibrating the matrix space with extramitochondrial Ca(2+) buffers. Ca(2+)-independent activity is seen following protonophore-mediated uncoupling, when uncoupling arises through alamethicin-mediated pore formation, or upon opening the permeability transition pore. Under the latter conditions, activity continues in the presence of excess EGTA but is somewhat enhanced by exogenous Ca(2+). The Ca(2+)-independent activity is best seen in media of high ionic strength and displays a broad pH optimum located between pH 8 and pH 8.5. It is strongly inhibited by bromoenol lactone but not by arachidonyl trifluoromethyl ketone, dithiothreitol, and other inhibitors of particular phospholipase A(2) classes. Immunoanalysis of mitochondria and mitochondrial subfractions shows that a membrane-bound protein is present that is recognized by antibody against an authentic iPLA(2) that was first found in P388D(1) cells. It is concluded that mitochondria contain a distinct Ca(2+)-independent phospholipase A(2) that is regulated by bioenergetic parameters. It is proposed that this enzyme, rather than the Ca(2+)-dependent type IIA phospholipase A(2), initiates the removal of poorly functioning mitochondria by processes involving autolysis.

Free fatty acids activate a vigorous Ca(2+):2H(+) antiport activity in yeast mitochondria

The accumulation and retention of Ca(2+) by yeast mitochondria (Saccharomyces cerevisiae) mediated by ionophore ETH 129 occurs with a variable efficiency in different preparations. Ineffective Ca(2+) transport and a depressed membrane potential occur in parallel, are exacerbated in parallel by exogenous free fatty acids, and are corrected in parallel by the addition of bovine serum albumin. Bovine serum albumin is not required to develop a high membrane potential when either Ca(2+) or ETH 129 are absent, and when both are present membrane potential is restored by the addition of EGTA in a concentration-dependent manner. Respiration and swelling data indicate that the permeability transition pore does not open in yeast mitochondria that are treated with Ca(2+) and ETH 129, whereas fatty acid concentration studies and the inaction of carboxyatractyloside indicate that fatty acid-derived uncoupling does not underlie the other observations. It is concluded that yeast mitochondria contain a previously unrecognized Ca(2+):2H(+) antiporter that is highly active in the presence of free fatty acids and leads to a futile cycle of Ca(2+) accumulation and release when exogenous Ca(2+) and ETH 129 are available. It is also shown that isolated yeast mitochondria degrade their phospholipids at a relatively rapid rate. The activity responsible is also previously unrecognized. It is Ca(2+)-independent, little affected by the presence or absence of a respiratory substrate, and leads to the hydrolysis of ester linkages at both the sn-1 and sn-2 positions of the glycerophospholipids. The products of this activity, through their actions on the antiporter, explain the variable behavior of yeast mitochondria treated with Ca(2+) plus ETH 129.

Phospholipids reacylation and palmitoylcoa control tumour necrosis factor-alpha sensitivity

From the hypothesis that in TNF-alpha-resistant cells the activity of mitochondrial phospholipase A2 could be reversed by a lysophospholipid acyltransferase, we report that the mitochondrial reacylation of phosphatidylcholine as phosphatidylethanolamine was considerably higher in C6 (TNF-alpha-resistant) than in WEHI-164 (TNF-alpha-sensitive) cells. TNF-alpha did not modify the phospholipids' reacylation in C6, while in WEHI-164 it was increased several-fold. These results suggest that TNF-alpha is not sufficient to restore the barrier permeability in sensitive cells, but may be enough to explain the absence of permeability change in resistant cells. AcylCoA esters, depending on whether the acyl group is unsaturated or saturated (palmitic acid), could control membrane permeability either by participating in the reacylation of phospholipids or keeping the pore in a closed state. The analysis of the endogenous acylCoA ester pools of both cell lines show that the amount of palmitoylCoA is higher in resistant than sensitive cell lines. TNF-alpha treatment does not change these results.

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.

Regulation of the mitochondrial Ca2+ uniporter by external adenine nucleotides: the uniporter behaves like a gated channel which is regulated by nucleotides and divalent cations

We have previously used measurements of uncoupler-enforced reverse activity to demonstrate that the mitochondrial Ca2+ uniporter is strongly inhibited by external EGTA plus free Mg2+, following a brief period of rapid activity. Using the same approach, we now show that in addition to divalent cations, the uniporter is regulated by external adenine nucleotides and by other components of the cytosol. Inhibition produced by EGTA plus free Mg2+ is reversed by spermine (EC0.5 approximately 40 microM) and reduced when mitochondria are purified by an isoosmotic density-gradient method. Under either condition, inhibition is restored by external adenine nucleotides in a concentration-dependent manner. The order of effectiveness is ATP > ADP > AMP, with the nucleoside adenosine being ineffective. Among nucleotide triphosphates, the order is ATP > CTP approximately UTP > GTP. The effectiveness of ATP (EC50 approximately 0.6 mM) is the same in mitochondria and mitoplasts, the same as that of AMPPNP, and is not altered by the presence of oligomycin, carboxyatractyloside, or AP5A, used alone or in combinations. These findings indicate that ATP acts at a site located on the outer surface of the inner membrane through a mechanism which does not require its hydrolysis. Phosphate also inhibits reverse uniport under some conditions (EC50 approximately 20 microM). The sites at which free ATP and free Mg2+ inhibit the uniporter can be distinguished by chymotrypsin treatment of mitoplasts, which eliminates the action of Mg2+ but does not affect the action of ATP. Data are interpreted within the context of a model in which the uniporter is considered to be a gated channel that is controlled, in part, by specific external effector sites that accept divalent cations or nucleotides. The possible consequences of the model for cell Ca2+ regulation by mitochondria and regulation of TCA cycle activity by the matrix free Ca2+ concentration are considered.

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.

The peptide mastoparan is a potent facilitator of the mitochondrial permeability transition

Mastoparan facilitates opening of the mitochondrial permeability transition pore through an apparent bimodal mechanism of action. In the submicromolar concentration range, the action of mastoparan is dependent upon the medium Ca2+ and phosphate concentration and is subject to inhibition by cyclosporin A. At concentrations above 1 microM, pore induction by mastoparan occurs without an apparent Ca2+ requirement and in a cyclosporin A insensitive manner. Studies utilizing phospholipid vesicles show that mastoparan perturbs bilayer membranes across both concentration ranges, through a mechanism which is strongly dependent upon transmembrane potential. However, solute size exclusion studies suggest that the pores formed in mitochondria in response to both low and high concentrations of mastoparan are the permeability transition pore. It is proposed that low concentrations of mastoparan influence the pore per se, with higher concentrations having the additional effect of depolarizing the mitochondrial inner membrane through an action exerted upon the lipid phase. It may be the combination of these effects which allow pore opening in the absence of Ca2+ and in the presence of cyclosporin A, although other interpretations remain viable. A comparison of the activities of mastoparan and its analog, MP14, on mitochondria and phospholipid vesicles provides an initial indication that a G-protein may participate in regulation of the permeability transition pore. These studies draw attention to peptides, in a broad sense, as potential pore regulators in cells, under both physiological and pathological conditions.

Characterization and ultrastructural localization of annexin VI from mitochondria

Annexin VI, a member of a family of related intracellular proteins that associate reversibly with membrane phospholipids in a Ca(2+)-dependent manner, has been purified from bovine liver mitochondria and characterized. Moreover, biochemical and immunocytochemical lines of evidence are presented which strongly suggest that annexin VI is closely associated with the cristae in the inner membrane of mitochondria. These findings are consistent with a calcium channel activity of annexin VI in mitochondria.

Liver cell necrosis: cellular mechanisms and clinical implications

Based on our current understanding, we have developed a provisional model for hepatocyte necrosis that may be applicable to cell necrosis in general (Figure 6). Damage to mitochondria appears to be a key early event in the progression to necrosis. At least two pathways may be involved. In the first, inhibition of oxidative phosphorylation in the absence of the MMPT leads to ATP depletion, ion dysregulation, and enhanced degradative hydrolase activity. If oxygen is present, toxic oxygen species may be generated and lipid peroxidation can occur. Subsequent cytoskeleton and plasma membrane damage result in plasma membrane bleb formation. These steps are reversible if the insult to the cell is removed. However, if injury continues, bleb rupture and cell lysis occur. In the second pathway, mitochondrial damage results in an MMPT. This step is irreversible and leads to cell death by as yet uncertain mechanisms. It is important to note that MMPT may occur secondary to changes in the first pathway (e.g. oxidative stress, increased Cai2+, and ATP depletion) and that all the "downstream events" occurring in the first pathway may result from MMPT (e.g., ATP depletion, ion dysregulation, or hydrolase activation). Proof of this model's applicability to cell necrosis in general awaits further validation. In this review, we have attempted to highlight the advances in our understanding of the cellular mechanisms of necrotic injury. Recent advances in this understanding have allowed scientists and clinicians a better comprehension of liver pathophysiology. This knowledge has provided new avenues of therapy and played a key role in the practice of hepatology as evidenced by advances in organ preservation. Understanding the early reversible events leading to cellular and subcellular damage will be key to prevention and treatment of liver disease. Hopefully, disease and injury specific preventive or pharmacological strategies can be developed based on this expanding data base.

Membrane permeability transition promoted by phosphate enhances 1-anilino-8-naphthalene sulfonate fluorescence in calcium-loaded liver mitochondria

Phosphate and a number of other compounds induce membrane permeability transition (MBT) in Ca(2+)-loaded mitochondria. 1-Anilino-8-naphthalene sulfonate (ANS) was used as a fluorescent probe to investigate perturbations on the inner membrane during MBT. Induction of MBT caused ANS fluorescence enhancement with a biphasic rate that reached a plateau. The enhancement is analogous to that reported for de-energization of mitochondria. The fluorescence level was independent of whether ANS was added before or at different times after phosphate. In the absence of ANS, fluorescence was low and remained unchanged. The initial time course of MBT, as followed by large-amplitude swelling, was similar to that of fluorescence enhancement. Ruthenium red, EGTA, ADP, and cyclosporin A inhibited the enhancement. Only EGTA + ADP (or ATP) reversed the enhancement when added after phosphate. Efflux of matrix Ca2+ by sodium acetate or A23187 did not alter ANS fluorescence. The binding parameters (Kd and number of binding sites) were not significantly different, but the fluorescence maximum was more than doubled after MBT. Although the fluorescence of bound ANS showed a nonlinear relationship, it was always higher (73.0 +/- 19.0%) after reaching the plateau. Since ANS binding to membranes is nonspecific, the exact mechanism of the enhanced fluorescence is not apparent. The dependence of the initial rate of fluorescence enhancement on Ca2+ concentration was nonlinear, with 45 microM at half-maximal rate. The dependence on phosphate was hyperbolic with 0.7 mM at half-maximal rate, which is close to the Km value of phosphate carrier. The kinetics is compatible with Ca2+ binding to some membrane component(s) during MBT and cause ANS fluorescence enhancement.(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphatidylethanolamine derived from phosphatidylserine is deacylated and reacylated in rat hepatocytes

The metabolism of phosphatidylserine (PS), phosphatidylethanolamine (PE) and phosphatidylcholine (PC), derived from [3H]serine, has been studied in rat hepatocytes. After an initial pulse with radioactivity for 10 min and a chase for up to 240 min, cells were harvested and PS, PE and PC isolated. At the end of the pulse, greater than 90% of [3H]serine derived phospholipid radioactivity was associated with PS. In the subsequent chase, newly-made PS was degraded rapidly with less than 25% of the label lost from PS appearing in the PE and PC pools. In contrast, [3H]serine-labeled PE turnover was not detectable. Very little newly-made PS was converted to PC. PE and PC were further fractionated into molecular species by high-performance liquid chromatography. We report that [3H]serine-labeled PE is deacylated/reacylated with the major product of remodeling being 18:0-20:4 PE. In contrast, [3H]serine-labeled PC is not significantly remodeled.