The mitochondrion is at the core of cellular energy metabolism, being the site of most ATP generation. Calcium is a key regulator of mitochondrial function and acts at several levels within the organelle to stimulate ATP synthesis. However, the dysregulation of mitochondrial Ca(2+) homeostasis is now recognized to play a key role in several pathologies. For example, mitochondrial matrix Ca(2+) overload can lead to enhanced generation of reactive oxygen species, triggering of the permeability transition pore, and cytochrome c release, leading to apoptosis. Despite progress regarding the independent roles of both Ca(2+) and mitochondrial dysfunction in disease, the molecular mechanisms by which Ca(2+) can elicit mitochondrial dysfunction remain elusive. This review highlights the delicate balance between the positive and negative effects of Ca(2+) and the signaling events that perturb this balance. Overall, a "two-hit" hypothesis is developed, in which Ca(2+) plus another pathological stimulus can bring about mitochondrial dysfunction.
SUMMARY The mitochondrion is the primary source of reactive oxygen species (ROS) in eukaryotic cells. With the aid of a novel mitochondrial matrix-targeted superoxide indicator, here we show that individual mitochondria undergo spontaneous bursts of superoxide generation, termed “superoxide flashes”. Superoxide flashes occur randomly in space and time, exhibit all-or-none properties, and reflect elementary events of superoxide production within single mitochondria across a wide diversity of cells. Individual flashes are triggered by transient openings of the mitochondrial permeability transition pore (mPTP) and are fueled by electron transfer complexes-dependent superoxide production. While decreased during cardiac hypoxia/anoxia, a flurry of superoxide flash activity contributes to the destructive rebound ROS burst observed during early reoxygenation after anoxia. The discovery of superoxide flashes reveals a novel mechanism for quantal ROS production by individual mitochondria and substantiates the central role of mPTP in oxidative stress related pathology in addition to its well-known role in apoptosis.
These findings indicate that the fission-mediated fragmentation of mitochondrial tubules is causally associated with enhanced production of mitochondrial ROS and cardiovascular cell injury in hyperglycaemic conditions.
Research over the last decade has extended the prevailing view of mitochondria to include functions well beyond the critical bioenergetics role in supplying ATP. It is now recognized that mitochondria play a crucial role in cell signaling events, inter-organelle communication, aging, many diseases, cell proliferation and cell death. Apoptotic signal transmission to the mitochondria results in the efflux of a number of potential apoptotic regulators to the cytosol that trigger caspase activation and lead to cell destruction. Accumulating evidence indicates that the voltage-dependent anion channel (VDAC) is involved in this release of proteins via the outer mitochondrial membrane. VDAC in the outer mitochondrial membrane is in a crucial position in the cell, forming the main interface between the mitochondrial and the cellular metabolisms. VDAC has been recognized as a key protein in mitochondria-mediated apoptosis since it is the proposed target for the pro- and anti-apoptotic Bcl2-family of proteins and due to its function in the release of apoptotic proteins located in the inter-membranal space. The diameter of the VDAC pore is only about 2.6-3 nm, which is insufficient for passage of a folded protein like cytochrome c. New work suggests pore formation by homo-oligomers of VDAC or hetero-oligomers composed of VDAC and pro-apoptotic proteins such as Bax or Bak. This review provides insights into the central role of VDAC in cell life and death and emphasizes its function in the regulation of mitochondria-mediated apoptosis and, thereby, its potential as a rational target for new therapeutics.
Mitochondrial fission and fusion are the main components mediating the dynamic change of mitochondrial morphology observed in living cells. While many protein factors directly participating in mitochondrial dynamics have been identified, upstream signals that regulate mitochondrial morphology are not well understood. In this study, we tested the role of intracellular Ca 2þ in regulating mitochondrial morphology. We found that treating cells with the ER Ca 2þ -ATPase inhibitor thapsigargin (TG) induced two phases of mitochondrial fragmentation. The initial fragmentation of mitochondria occurs rapidly within minutes dependent on an increase in intracellular Ca 2þ levels, and Ca 2þ influx into mitochondria is necessary for inducing mitochondrial fragmentation. The initial mitochondrial fragmentation is a transient event, as tubular mitochondrial morphology was restored as the Ca 2þ level decreased. We were able to block the TG-induced mitochondrial fragmentation by inhibiting mitochondrial fission proteins DLP1/Drp1 or hFis1, suggesting that increased mitochondrial Ca 2þ acts upstream to activate the cellular mitochondrial fission machinery. We also found that prolonged incubation with TG induced the second phase of mitochondrial fragmentation, which was non-reversible and led to cell death as reported previously. These results suggest that Ca 2þ is involved in controlling mitochondrial morphology via intra-mitochondrial Ca 2þ signaling as well as the apoptotic process.
Aims: Mitochondrial Ca 2+ homeostasis is crucial for balancing cell survival and death. The recent discovery of the molecular identity of the mitochondrial Ca 2+ uniporter pore (MCU) opens new possibilities for applying genetic approaches to study mitochondrial Ca 2+ regulation in various cell types, including cardiac myocytes. Basal tyrosine phosphorylation of MCU was reported from mass spectroscopy of human and mouse tissues, but the signaling pathways that regulate mitochondrial Ca 2+ entry through posttranslational modifications of MCU are completely unknown. Therefore, we investigated a 1 -adrenergic-mediated signal transduction of MCU posttranslational modification and function in cardiac cells. Results: a 1 -adrenoceptor (a 1 -AR) signaling translocated activated proline-rich tyrosine kinase 2 (Pyk2) from the cytosol to mitochondrial matrix and accelerates mitochondrial Ca 2+ uptake via Pyk2-dependent MCU phosphorylation and tetrametric MCU channel pore formation. Moreover, we found that a 1 -AR stimulation increases reactive oxygen species production at mitochondria, mitochondrial permeability transition pore activity, and initiates apoptotic signaling via Pyk2-dependent MCU activation and mitochondrial Ca 2+ overload. Innovation: Our data indicate that inhibition of a 1 -AR-Pyk2-MCU signaling represents a potential novel therapeutic target to limit or prevent mitochondrial Ca 2+ overload, oxidative stress, mitochondrial injury, and myocardial death during pathophysiological conditions, where chronic adrenergic stimulation is present. Conclusion: The a 1 -AR-Pyk2-dependent tyrosine phosphorylation of the MCU regulates mitochondrial Ca 2+ entry and apoptosis in cardiac cells. Antioxid. Redox Signal. 21, 863-879.
Rationale: Lipid overload-induced heart dysfunction is characterized by cardiomyocyte death, myocardial remodeling, and compromised contractility, but the impact of excessive lipid supply on cardiac function remains poorly understood. Objective: To investigate the regulation and function of the mitochondrial fission protein Drp1 (dynamin-related protein 1) in lipid overload-induced cardiomyocyte death and heart dysfunction. Methods and Results: Mice fed a high-fat diet (HFD) developed signs of obesity and type II diabetes mellitus, including hyperlipidemia, hyperglycemia, hyperinsulinemia, and hypertension. HFD for 18 weeks also induced heart hypertrophy, fibrosis, myocardial insulin resistance, and cardiomyocyte death. HFD stimulated mitochondrial fission in mouse hearts. Furthermore, HFD increased the protein level, phosphorylation (at the activating serine 616 sites), oligomerization, mitochondrial translocation, and GTPase activity of Drp1 in mouse hearts, indicating that Drp1 was activated. Monkeys fed a diet high in fat and cholesterol for 2.5 years also exhibited myocardial damage and Drp1 activation in the heart. Interestingly, HFD decreased nicotinamide adenine dinucleotide (oxidized) levels and increased Drp1 acetylation in the heart. In adult cardiomyocytes, palmitate increased Drp1 acetylation, phosphorylation, and protein levels, and these increases were abolished by restoration of the decreased nicotinamide adenine dinucleotide (oxidized) level. Proteomics analysis and in vitro screening revealed that Drp1 acetylation at lysine 642 (K642) was increased by HFD in mouse hearts and by palmitate incubation in cardiomyocytes. The nonacetylated Drp1 mutation (K642R) attenuated palmitate-induced Drp1 activation, its interaction with voltage-dependent anion channel 1, mitochondrial fission, contractile dysfunction, and cardiomyocyte death. Conclusions: These findings uncover a novel mechanism that contributes to lipid overload-induced heart hypertrophy and dysfunction. Excessive lipid supply created an intracellular environment that facilitated Drp1 acetylation, which, in turn, increased its activity and mitochondrial translocation, resulting in cardiomyocyte dysfunction and death. Thus, Drp1 may be a critical mediator of lipid overload-induced heart dysfunction as well as a potential target for therapy.
Mitochondria are dynamic organelles that constantly undergo fission, fusion, and movement. Increasing evidence indicates that these dynamic changes are intricately related to mitochondrial function, suggesting that mitochondrial form and function are linked. Calcium (Ca2+) is one signal that has been shown to both regulate mitochondrial fission in various cells types and stimulate mitochondrial enzymes involved in ATP generation. However, although Ca2+ plays an important role in the adult cardiac muscle cells for excitation-metabolism coupling, little is known about whether Ca2+ can regulate their mitochondrial morphology. Therefore, we tested the role of Ca2+ in regulating cardiac mitochondrial fission. We found that neonatal and adult cardiomyocyte mitochondria undergo rapid and transient fragmentation upon a thapsigargin (TG)- or KCl-induced cytosolic Ca2+ increase. The mitochondrial fission protein, DLP1, participates in this mitochondrial fragmentation, suggesting that cardiac mitochondrial fission machinery may be regulated by intracellular Ca2+ signaling. Moreover, the TG-induced fragmentation was also associated with an increase in reactive oxygen species (ROS) formation, suggesting that activation of mitochondrial fission machinery is an early event for Ca2+-mediated ROS generation in cardiac myocytes. These results suggest that Ca2+, an important regulator of muscle contraction and energy generation, also dynamically regulates mitochondrial morphology and ROS generation in cardiac myocytes.
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