Non-conventional mitochondrial permeability transition: Its regulation by mitochondrial dynamics

Mitochondrial permeability transition (MPT) is a phenomenon that the inner mitochondrial membrane (IMM) loses its selective permeability, leading to mitochondrial dysfunction and cell injury. Electrophysiological evidence indicates the presence of a mega-channel commonly called permeability transition pore (PTP) whose opening is responsible for MPT. However, the molecular identity of the PTP is still under intensive investigations and debates, although cyclophilin D that is inhibited by cyclosporine A (CsA) is the established regulatory component of the PTP. PTP can also open transiently and functions as a rapid mitochondrial Ca²⁺ releasing mechanism. Mitochondrial fission and fusion, the main components of mitochondrial dynamics, control the number and size of mitochondria, and have been shown to play a role in regulating MPT directly or indirectly. Studies by us and others have indicated the potential existence of a form of transient MPT that is insensitive to CsA. This “non-conventional” MPT is regulated by mitochondrial dynamics and may serve a protective role possibly by decreasing the susceptibility for a frequent or sustained PTP opening; hence, it may have a therapeutic value in many disease conditions involving MPT.     

The Cratylia mollis Seed Lectin Induces Membrane Permeability Transition in Isolated Rat Liver Mitochondria and a Cyclosporine A‐Insensitive Permeability Transition in Trypanosoma cruzi Mitochondria

Previous results provided evidence that Cratylia mollis seed lectin (Cramoll 1,4) promotes Trypanosoma cruzi epimastigotes death by necrosis via a mechanism involving plasma membrane permeabilization to Ca²⁺ and mitochondrial dysfunction due to matrix Ca²⁺ overload. In order to investigate the mechanism of Ca²⁺‐induced mitochondrial impairment, experiments were performed analyzing the effects of this lectin on T. cruzi mitochondrial fraction and in isolated rat liver mitochondria (RLM), as a control. Confocal microscopy of T. cruzi whole cell revealed that Cramoll 1,4 binding to the plasma membrane glycoconjugates is followed by its internalization and binding to the mitochondrion. Electrical membrane potential (?Ψ_m) of T. cruzi mitochondrial fraction suspended in a reaction medium containing 10 μM Ca²⁺ was significantly decreased by 50 μg/ml Cramoll 1,4 via a mechanism insensitive to cyclosporine A (CsA, membrane permeability transition (MPT) inhibitor), but sensitive to catalase or 125 mM glucose. In RLM suspended in a medium containing 10 μM Ca²⁺ this lectin, at 50 μg/ml, induced increase in the rate of hydrogen peroxide release, mitochondrial swelling, and ?Ψ_m disruption. All these mitochondrial alterations were sensitive to CsA, catalase, and EGTA. These results indicate that Cramoll 1, 4 leads to inner mitochondrial membrane permeabilization through Ca²⁺ dependent mechanisms in both mitochondria. The sensitivity to CsA in RLM characterizes this lectin as a MPT inducer and the lack of CsA effect identifies a CsA‐insensitive MPT in T. cruzi mitochondria.     

Mitochondrial Dysfunction in the Pathogenesis of Necrotic and Apoptotic Cell Death

Mitochondria are frequently the target of injury after stresses leading to necrotic and apoptoticcell death. Inhibition of oxidative phosphorylation progresses to uncoupling when opening ofa high conductance permeability transition (PT) pore in the mitochondrial inner membraneabruptly increases the permeability of the mitochondrial inner membrane to solutes of molecularmass up to 1500 Da. Cyclosporin A (CsA) blocks this mitochondrial permeability transition(MPT) and prevents necrotic cell death from oxidative stress, Ca²⁺ ionophore toxicity,Reye-related drug toxicity, pH-dependent ischemia/reperfusion injury, and other models of cell injury.Confocal fluorescence microscopy directly visualizes onset of the MPT from the movementof green-fluorescing calcein into mitochondria and the simultaneous release from mitochondriaof red-fluorescing tetramethylrhodamine methylester, a membrane potential-indicatingfluorophore. In oxidative stress to hepatocytes induced by tert-butylhydroperoxide, NAD(P)Hoxidation, increased mitochondrial Ca²⁺, and mitochondrial generation of reactive oxygen speciesprecede and contribute to onset of the MPT. Confocal microscopy also shows directly thatthe MPT is a critical event in apoptosis of hepatocytes induced by tumor necrosis factor-.Progression to necrotic and apoptotic cell killing depends, at least in part, on the effect theMPT has on cellular ATP levels. If ATP levels fall profoundly, necrotic killing ensues. If ATPlevels are at least partially maintained, apoptosis follows the MPT. Cellular features of bothapoptosis and necrosis frequently occur together after death signals and toxic stresses. A newterm, necrapoptosis, describes such death processes that begin with a common stress or deathsignal, progress by shared pathways, but culminate in either cell lysis (necrosis) or programmedcellular resorption (apoptosis) depending on modifying factors such as ATP.     

Cyclosporin a Increases Mitochondrial Calcium Uptake Capacity in Cortical Astrocytes but not Cerebellar Granule Neurons

Isolated brain mitochondria are a heterogeneous mixture from different cell types and these subsets may have differing sensitivities to Ca²⁺-induced membrane permeability transition (MPT) and to inhibition of the MPT by cyclosporin A (CsA). This study tested the hypothesis that mitochondria within primary cultures of astrocytes and neurons exhibit different energy-dependent Ca²⁺ uptake capacities and different degrees to which CsA increases their uptake capacity. Astrocytes and neurons were suspended in a cytosol-like medium containing respiratory substrates, ATP, and Mg²⁺ in the presence of digitonin to selectively permeabilize the plasma membrane. Uptake of added Ca²⁺ by mitochondria within the cells was measured by Calcium Green 5N fluorescent monitoring of the medium [Ca²⁺]. Permeabilized astrocytes had a fourfold higher Ca²⁺ uptake capacity, relative to neurons and a twofold higher content based on relative contents of mitochondria assessed by measurements of mitochondrial DNA and cytochrome oxidase subunit 1 protein. In astrocytes the Ca²⁺ uptake capacity was increased twofold by preincubation with 2–5 μM CsA, while in neurons CsA had no effect. Similar results were obtained using measurements of the effects of added Ca²⁺ on mitochondrial membrane potential. FK506, a drug similar to CsA but without MPT inhibitory activity, had no effect on either cell type. These results are consistent with the presence of a calcium-induced MPT in astrocytes, even in the presence of ATP, and indicate that the MPT in cerebellar granule neurons is resistant to CsA inhibition. Some of the protective effects of CsA in vivo may therefore be mediated by preservation of mitochondrial functional integrity within astrocytes.     

Spectroscopic and Microscopic Studies on the Mechanisms of Mitochondrial Toxicity Induced by Different Concentrations of Cadmium

The deleterious action of Cd²⁺ on rat liver mitochondria was investigated in this work using spectroscopic and microscopic methods. The concentration dependence of Cd²⁺ on mitochondrial swelling, membrane potential and membrane fluidity was studied. Our aim was to detect the active sites of Cd²⁺ in the mitochondrial membrane treatments with cyclosporin A (CsA) and EGTA on the mitochondrial permeability transition (MPT) induced by low and high concentrations of Cd²⁺. The protective effects of dithiothreitol, human serum albumin and monobromobimane⁺ on Cd²⁺-induced MPT were also monitored. All of these investigations indicated that Cd²⁺ can directly affect MPT at two separate localization sites at different concentrations: the classic Ca²⁺ triggering site and the thiol (–SH) groups of membrane proteins matched by MPT pore opening (defined as “S” site). At the high concentration of Cd²⁺, other free –SH groups in the mitochondrial matrix may be involved in this process. These findings were supported by transmission electron microscopy and shed light on the toxic mechanism of Cd²⁺ on mitochondria.     

Calcium Induces Mitochondrial Oxidative Stress Because of its Binding to Adenine Nucleotide Translocase

Several studies have demonstrated that the mitochondrial membrane switches from selective to non-selective permeability because of its improved matrix Ca²⁺ accumulation and oxidative stress. This process, known as permeability transition, evokes severe dysfunction in mitochondria through the opening of a non-specific pore, whose chemical nature is still under discussion. There are some proposals regarding the components of the pore structure, e.g., the adenine nucleotide translocase and dimers of the F1 Fo-ATP synthase. Our results reveal that Ca²⁺ induces oxidative stress, which not only increases lipid peroxidation and ROS generation but also brings about both the collapse of the transmembrane potential and the membrane release of cytochrome c. Additionally, it is shown that Ca²⁺ increases the binding of the probe eosin-5-maleimide to adenine nucleotide translocase. Interestingly, these effects are diminished after the addition of ADP. It is suggested that pore opening is caused by the binding of Ca²⁺ to the adenine nucleotide translocase.     

Mitochondrial ATP-Sensitive K<Superscript>+</Superscript> Channels Prevent Oxidative Stress,Permeability Transition and Cell Death

Ischemia followed by reperfusion results in impairment of cellular and mitochondrial functionality due to opening of mitochondrial permeability transition pores. On the other hand, activation of mitochondrial ATP-sensitive K⁺ channels (mitoK_ATP) protects the heart against ischemic damage. This study examined the effects of mitoK_ATP and mitochondrial permeability transition on isolated rat heart mitochondria and cardiac cells submitted to simulated ischemia and reperfusion (cyanide/aglycemia). Both mitoK_ATP opening, using diazoxide, and the prevention of mitochondrial permeability transition, using cyclosporin A, protected against cellular damage, without additive effects. MitoK_ATP opening in isolated rat heart mitochondria slightly decreased Ca²⁺ uptake and prevented mitochondrial reactive oxygen species production, most notably in the presence of added Ca²⁺. In ischemic cells, diazoxide decreased ROS generation during cyanide/aglycemia while cyclosporin A prevented oxidative stress only during simulated reperfusion. Collectively, these studies indicate that opening mitoK_ATP prevents cellular death under conditions of ischemia/reperfusion by decreasing mitochondrial reactive oxygen species release secondary to Ca²⁺ uptake, inhibiting mitochondrial permeability transition.     

Investigation of Calcium Accumulation in Mitochondria in Cells Undergoing Apoptosis

One of the earliest features of apoptosis is the induction of the mitochondrial permeability transition (MPT) due to opening of a pore in the mitochondrial membrane. We estimated the Ca²⁺ capacity of mitochondria (a threshold level of Ca²⁺ that induces the release of this cation from mitochondria) during apoptosis. Incubation of thymocytes at 37°C for 4 h equally decreased the mitochondrial Ca²⁺ capacity both in the presence and the absence of dexamethasone, an inducer of apoptosis. At the same time, dexamethasone significantly stimulated internucleosomal DNA fragmentation, which is one of the manifestations of apoptosis. Cyclosporin A prevented the time-dependent decrease in the Ca²⁺ capacity of mitochondria but did not affect internucleosomal DNA fragmentation. Therefore, induction of apoptosis assessed by internucleosomal DNA fragmentation is not mediated by the mitochondrial permeability transition.     

Role of the mitochondrial membrane permeability transition in cell death

In recent years, the role of the mitochondria in both apoptotic and necrotic cell death has received considerable attention. An increase of mitochondrial membrane permeability is one of the key events in apoptotic or necrotic death, although the details of the mechanism involved remain to be elucidated. The mitochondrial membrane permeability transition (MPT) is a Ca²⁺-dependent increase of mitochondrial membrane permeability that leads to loss of Δψ, mitochondrial swelling, and rupture of the outer mitochondrial membrane. The MPT is thought to occur after the opening of a channel that is known as the permeability transition pore (PTP), which 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). Recently, significant progress has been made by studies performed with mice lacking Cyp D at several laboratories, which have convincingly demonstrated that Cyp D is essential for the MPT to occur and that the Cyp D-dependent MPT regulates some forms of necrotic, but not apoptotic, cell death. Cyp D-deficient mice have also been used to show that the Cyp D-dependent MPT plays a crucial role in ischemia/reperfusion injury. The anti-apoptotic proteins Bcl-2 and Bcl-x_L have the ability to block the MPT, and can therefore block MPT-dependent necrosis in addition to their well-established ability to inhibit apoptosis.     

Effect of taurine on ischemia–reperfusion injury

Taurine is an abundant β-amino acid that regulates several events that dramatically influence the development of ischemia–reperfusion injury. One of these events is the extrusion of taurine and Na⁺ from the cell via the taurine/Na⁺ symport. The loss of Na⁺ during the ischemia–reperfusion insult limits the amount of available Na⁺ for Na⁺/Ca²⁺ exchange, an important process in the development of Ca²⁺ overload and the activation of the mitochondrial permeability transition, a key process in ischemia–reperfusion mediated cell death. Taurine also prevents excessive generation of reactive oxygen species by the respiratory chain, an event that also limits the activation of the MPT. Because taurine is an osmoregulator, changes in taurine concentration trigger “osmotic preconditioning,” a process that activates an Akt-dependent cytoprotective signaling pathway that inhibits MPT pore formation. These effects of taurine have clinical implications, as experimental evidence reveals potential promise of taurine therapy in preventing cardiac damage during bypass surgery, heart transplantation and myocardial infarction. Moreover, severe loss of taurine from the heart during an ischemia–reperfusion insult may increase the risk of ventricular remodeling and development of heart failure.     

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.     

Translocation of iron from lysosomes to mitochondria during ischemia predisposes to injury after reperfusion in rat hepatocytes

The mitochondrial permeability transition (MPT) initiated by reactive oxygen species (ROS) plays an essential role in ischemia–reperfusion (IR) injury. Iron is a critical catalyst for ROS formation, and intracellular chelatable iron promotes oxidative injury-induced and MPT-dependent cell death in hepatocytes. Accordingly, our aim was to investigate the role of chelatable iron in IR-induced ROS generation, MPT formation, and cell death in primary rat hepatocytes. To simulate IR, overnight-cultured hepatocytes were incubated anoxically at pH 6.2 for 4 h and reoxygenated at pH 7.4. Chelatable Fe²⁺, ROS, and mitochondrial membrane potential were monitored by confocal fluorescence microscopy of calcein, chloromethyldichlorofluorescein, and tetramethylrhodamine methyl ester, respectively. Cell killing was assessed by propidium iodide fluorimetry. Ischemia caused progressive quenching of cytosolic calcein by more than 90%, signifying increased chelatable Fe²⁺. Desferal and starch–desferal 1 h before ischemia suppressed calcein quenching. Ischemia also induced quenching and dequenching of calcein loaded into mitochondria and lysosomes, respectively. Desferal, starch–desferal, and the inhibitor of the mitochondrial Ca²⁺ uniporter (MCU), Ru360, suppressed mitochondrial calcein quenching during ischemia. Desferal, starch–desferal, and Ru360 before ischemia also decreased mitochondrial ROS formation, MPT opening, and cell killing after reperfusion. These results indicate that lysosomes release chelatable Fe²⁺ during ischemia, which is taken up into mitochondria by MCU. Increased mitochondrial iron then predisposes to ROS-dependent MPT opening and cell killing after reperfusion.     

The yeast mitochondrial permeability transition is regulated by reactive oxygen species,endogenous Ca2+ and Cpr3, mediating cell death

We investigated the properties of the permeability transition pore (PTP) in Saccharomyces cerevisiae in agar-embedded mitochondria (AEM) and agar-embedded cells (AEC) and its role in yeast death. In AEM, ethanol-induced pore opening, as indicated by the release of calcein and mitochondrial membrane depolarization, can be inhibited by CsA, by Cpr3 deficiency, and by the antioxidant glutathione. Notably, the pore opening is inhibited, when mitochondria are preloaded by EGTA or Fluo3 to chelate matrix Ca²⁺, or are pretreated with 4-Br A23187 to extract matrix Ca²⁺, prior to agar-embedding, or when pore opening is induced in the presence of EGTA; opened pores are re-closed by sequential treatment with CsA, 4-Br A23187 plus EGTA and NADH, indicating endogenous matrix Ca²⁺ involvement. CsA also inhibits the pore opening with low conductance triggered by exogenous Ca²⁺ transport with ETH129. In AEC, the treatment of tert-butylhydroperoxide, a pro-oxidant that triggers transient pore opening in high conductance in AEM, induces yeast death, which is also dependent on CsA and Cpr3. Furthermore, AEMs from mutants lacking three ADP/ATP carrier (AAC) isoforms and with defective ATP synthase dimerization exhibit high and low conductance pore openings with CsA sensitivity, respectively. Collectively, these data show that the yeast PTP is regulated by Cpr3, endogenous matrix Ca²⁺, and reactive oxygen species, and that it is involved in yeast death; furthermore, ATP synthase dimers play a key role in CsA-sensitive pore formation, while AACs are dispensable.     

Role of the mitochondrial permeability transition in apoptotic and necrotic death after ischemia/reperfusion injury to hepatocytes

Reperfusion of ATP-depleted tissues after warm or cold ischemia causes pH-dependent necrotic and apoptotic cell death. In hepatocytes and other cell types as well, the mechanism underlying this reperfusion-induced cell death involves onset of the mitochondrial permeability transition (MPT). Opening of permeability transition (PT) pores in the mitochondrial inner membrane initiates the MPT, an event blocked by cyclosporin A (CsA) and pH less than 7.4. Thus, both acidotic pH and CsA prevent MPT-dependent reperfusion injury. Glycine also blocks reperfusion-induced necrosis but acts downstream of PT pore opening by stabilizing the plasma membrane. After the MPT, ATP availability from glycolysis or other source determines whether cell injury after reperfusion progresses to ATP depletion-dependent necrosis or ATP-requiring apoptosis. Thus, apoptosis and necrosis after reperfusion share a common pathway, the MPT. Cell injury progressing to either necrosis or apoptosis by shared pathways can be more aptly termed necrapoptosis.     

Multi-parameter Measurement of the Permeability Transition Pore Opening in Isolated Mouse Heart Mitochondria

The mitochondrial permeability transition pore (mtPTP) is a non specific channel that forms in the inner mitochondrial membrane to transport solutes with a molecular mass smaller than 1.5 kDa. Although the definitive molecular identity of the pore is still under debate, proteins such as cyclophilin D, VDAC and ANT contribute to mtPTP formation. While the involvement of mtPTP opening in cell death is well established¹, accumulating evidence indicates that the mtPTP serves a physiologic role during mitochondrial Ca²⁺ homeostasis², bioenergetics and redox signaling ³.mtPTP opening is triggered by matrix Ca²⁺ but its activity can be modulated by several other factors such as oxidative stress, adenine nucleotide depletion, high concentrations of Pi, mitochondrial membrane depolarization or uncoupling, and long chain fatty acids⁴. In vitro, mtPTP opening can be achieved by increasing Ca²⁺ concentration inside the mitochondrial matrix through exogenous additions of Ca²⁺ (calcium retention capacity). When Ca²⁺ levels inside mitochondria reach a certain threshold, the mtPTP opens and facilitates Ca²⁺ release, dissipation of the proton motive force, membrane potential collapse and an increase in mitochondrial matrix volume (swelling) that ultimately leads to the rupture of the outer mitochondrial membrane and irreversible loss of organelle function.Here we describe a fluorometric assay that allows for a comprehensive characterization of mtPTP opening in isolated mouse heart mitochondria. The assay involves the simultaneous measurement of 3 mitochondrial parameters that are altered when mtPTP opening occurs: mitochondrial Ca²⁺ handling (uptake and release, as measured by Ca²⁺ concentration in the assay medium), mitochondrial membrane potential, and mitochondrial volume. The dyes employed for Ca²⁺ measurement in the assay medium and mitochondrial membrane potential are Fura FF, a membrane impermeant, ratiometric indicator which undergoes a shift in the excitation wavelength in the presence of Ca²⁺, and JC-1, a cationic, ratiometric indicator which forms green monomers or red aggregates at low and high membrane potential, respectively. Changes in mitochondrial volume are measured by recording light scattering by the mitochondrial suspension. Since high-quality, functional mitochondria are required for the mtPTP opening assay, we also describe the steps necessary to obtain intact, highly coupled and functional isolated heart mitochondria.     

The mitochondrial permeability transition in toxic, hypoxic and reperfusion injury

Opening of a non-specific, high conductance permeability transition pore or megachannel in the inner mitochondrial membrane causes onset of the mitochondrial permeability transition, which is characterized by mitochondrial swelling, depolarization and uncoupling. Inducers of the permeability transition include Ca²⁺, oxidant stress and a permissive pH greater than 7.0. Blockers include cyclosporin A, trifluoperazine and pH < 7. Using laser scanning confocal microscopy, we developed techniques to visualize onset of the mitochondrial permeability transition in situ in living cells. In untreated cells, the permeability transition pore is continuously closed and does not 'flicker' open. By contrast, the pore opens in liver and heart cells after exposure to oxidant chemicals, calcium ionophore, hypoxia and ischemia/reperfusion, causing mitochondrial uncoupling and aggravation of ATP depletion. In injury to hepatocytes from tert-butylhydroperoxide, an analog of lipid hydroperoxides generated during oxidative stress, onset of the mitochondrial permeability transition is preceded by oxidation of mitochondrial pyridine nucleotides, mitochondrial generation of oxygen radicals and an increase of mitochondrial Ca²⁺, all inducers of the mitochondrial permeability transition. In ischemia, the acidosis of anaerobic metabolism protects strongly against cell death. During reperfusion, recovery of pH to normal levels is a stress that actually precipitates cell killing. Onset of the mitochondrial permeability transition may be responsible, in part, for this pH-dependent injury, or pH paradox. The mitochondrial permeability transition may also be responsible for a variety of pathological phenomena. In particular, the mitochondrial permeability transition may underlie Reye's syndrome and Reye's-like drug toxicities. In conclusion, multiple mechanisms contribute to cell injury after hypoxia, ischemia/reperfusion and toxic chemicals, but a common final pathway leading to acute cellular nec rosis may be ATP depletion after mitochondrial failure. One important mechanism causing mitochondrial failure is the mitochondrial permeability transition, which both uncouples oxidative phosphorylation and accelerates ATP hydrolysis. Interventions that block this pH-dependent phenomenon protect against onset of cell death. (Mol Cell Biochem 174: 159–165, 1997)     

Mitochondrial Ca<Superscript>2+</Superscript> and regulation of the permeability transition pore

The mitochondrial permeability transition pore was originally described in the 1970’s as a Ca²⁺ activated pore and has since been attributed to the pathogenesis of many diseases. Here we evaluate how each of the current models of the pore complex fit to what is known about how Ca²⁺ regulates the pore, and any insight that provides into the molecular identity of the pore complex. We also discuss the central role of Ca²⁺ in modulating the pore’s open probability by directly regulating processes, such as ATP/ADP balance through the tricarboxylic acid cycle, electron transport chain, and mitochondrial membrane potential. We review how Ca²⁺ influences second messengers such as reactive oxygen/nitrogen species production and polyphosphate formation. We discuss the evidence for how Ca²⁺ regulates post-translational modification of cyclophilin D including phosphorylation by glycogen synthase kinase 3 beta, deacetylation by sirtuins, and oxidation/ nitrosylation of key residues. Lastly we introduce a novel view into how Ca²⁺ activated proteolysis through calpains in the mitochondria may be a driver of sustained pore opening during pathologies such as ischemia reperfusion injury.     

Ischemic Postconditioning Reduces NMDA Receptor Currents Through the Opening of the Mitochondrial Permeability Transition Pore and KATP Channel in Mouse Neurons

Ischemic postconditioning (PostC) is known to reduce cerebral ischemia/reperfusion (I/R) injury; however, whether the opening of mitochondrial ATP-dependent potassium (mito-K_ATP) channels and mitochondrial permeability transition pore (mPTP) cause the depolarization of the mitochondrial membrane that remains unknown. We examined the involvement of the mito-K_ATP channel and the mPTP in the PostC mechanism. Ischemic PostC consisted of three cycles of 15 s reperfusion and 15 s re-ischemia, and was started 30 s after the 7.5 min ischemic load. We recorded N-methyl-d-aspartate receptors (NMDAR)-mediated currents and measured cytosolic Ca²⁺ concentrations, and mitochondrial membrane potentials in mouse hippocampal pyramidal neurons. Both ischemic PostC and the application of a mito-K_ATP channel opener, diazoxide, reduced NMDAR-mediated currents, and suppressed cytosolic Ca²⁺ elevations during the early reperfusion period. An mPTP blocker, cyclosporine A, abolished the reducing effect of PostC on NMDAR currents. Furthermore, both ischemic PostC and the application of diazoxide potentiated the depolarization of the mitochondrial membrane potential. These results indicate that ischemic PostC suppresses Ca²⁺ influx into the cytoplasm by reducing NMDAR-mediated currents through mPTP opening. The present study suggests that depolarization of the mitochondrial membrane potential by opening of the mito-K_ATP channel is essential to the mechanism of PostC in neuroprotection against anoxic injury.

     

Role of mitochondria in the immune response to cancer: a central role for Ca2+

This study demonstrates that Ca²⁺ stimulates mitochondrial energy metabolism during spleen lymphocyte activation in response to the ascitic Walker 256 tumor in rats. Intracellular Ca²⁺ concentrations, phosphorylated protein kinase C (pPKC) levels, Bcl-2 protein contents, interleukin-2 (IL-2) levels, mitochondrial uncoupling protein-2 (UCP-2) contents and reactive oxygen species (ROS) were significantly elevated in these activated lymphocytes. Mitochondria of activated lymphocytes exhibited high free Ca²⁺ concentrations in the matrix and enhanced oligomycin-sensitive oxygen consumption, indicating an increased rate of oxidative phosphorylation. The production of ROS was largely decreased by diphenylene iodinium in the activated lymphocytes, suggesting that NADPH oxidase is the prevalent source of these species. Accumulation of UCP-2 and the anti-apoptotic protein Bcl-2 is probably important to prevent mitochondrial dysfunction and cell death elicited by the sustained high levels of intracellular Ca²⁺ and ROS and may explain the observed higher resistance from activated lymphocytes against the opening of the mitochondrial membrane permeability pore (MPT). All these changes were blocked by pretreatment of the rats with verapamil, an L-type Ca²⁺ channel antagonist. These data demonstrate a central role of Ca²⁺ in the control of mitochondrial bioenergetics in spleen lymphocytes during the immune response to cancer.     

Transport of Ca2+ and Ca2+-dependent permeability transition in heart mitochondria in the early stages of Duchenne muscular dystrophy

Duchenne muscular dystrophy (DMD) is a progressive skeletal muscle disease that is associated with severe cardiac complications in the late stages. Significant mitochondrial dysfunction is reportedly responsible for the development of cardiomyopathy with age. At the same time, adaptive changes in mitochondrial metabolism in cardiomyocytes were identified in the early stages of DMD. In this work, we evaluate the functioning of calcium transport systems (MCU and NCLX), and MPT pore in the heart mitochondria of young dystrophin-deficient mice. As compared to wild-type animals, heart mitochondria of mdx mice have been found to be more efficient both in respect to Ca²⁺ uniport and Na⁺-dependent Ca²⁺ efflux. The data obtained indicate that the increased rate of Ca²⁺ uptake by heart mitochondria of mdx mice may be due to an increase in the ratio of MCU and MCUb subunits. In turn, an increase in the rate of Ca²⁺ efflux from organelles in DMD may be the result of a significant increase in the level of NCLX. Moreover, the heart mitochondria of mdx mice were more resistant to MPT pore opening, which may be due to an increase in the microviscosity of mitochondrial membranes of DMD mice. At the same time, the level of putative MPT pore proteins did not change. The paper discusses the effect of rearrangements of the mitochondrial proteome involved in the transport and accumulation of calcium on the adaptation of this organ to DMD.