Protein folding and unfolding: proline cis - trans isomerization at the c subunits of F 1 F O -ATPase might open a high conductance ion channel

The c subunits, which constitutes the c-ring apparatus of the F F -ATPase, could be the main components of the mitochondrial permeability transition pore (mPTP). The well-known modulator of the mPTP formation and opening is the cyclophilin D (CyPD), a peptidyl-prolyl cis- trans isomerase. On the loop, which connects the two hairpin α-helix of c subunit, is present the unique proline residue (Pro ) that could be a biological target of CyPD. Indeed, the proline cis- trans isomerization might provide the switch that interconverts the open/closed states of the pore by pulling out the c-ring lipid plug.

Cardioprotection of Immature Heart by Simultaneous Activation of PKA and EPAC : A Role for the Mitochondrial Permeability Transition Pore

Metabolic and ionic changes during ischaemia predispose the heart to the damaging effects of reperfusion. Such changes and the resulting injury differ between immature and adult heart. Therefore, cardioprotective strategies for adults need to be tested in immature heart. We have recently shown that simultaneous activation of PKA and EPAC confers marked cardioprotection in adult hearts. The aim of this study is to investigate the efficacy of this intervention in immature hearts and determine whether the mitochondrial permeability transition pore (MPTP) is involved. Isolated perfused Langendorff hearts from both adult and immature rats were exposed to global ischaemia and reperfusion injury (I/R) following control perfusion or perfusion after an equilibra-tion period with activators of PKA and/or EPAC. Functional outcome and reperfusion injury were measured and in parallel, mitochondria were isolated following 5 min reperfusion to determine whether cardioprotective interventions involved changes in MPTP opening behaviour. Perfusion for 5 minutes preceding ischaemia of injury- matched adult and immature hearts with 5 µM 8-Br (8-Br-cAMP-AM), an activator of both PKA and EPAC, led to significant reduction in post-reperfusion CK release and infarct size. Perfusion with this agent also led to a reduction in MPTP opening propensity in both adult and immature hearts. These data show that immature hearts are innately more resistant to I/R injury than adults, and that this is due to a reduced ten-dency to MPTP opening following reperfusion. Further, simultaneous stimulation of PKA & EPAC causes cardioprotection which is additive to the innate resistance.

Regulation of Kidney Mitochondrial Function by Caloric Restriction

Caloric restriction (CR) prevents obesity, promotes healthy aging, and increases resilience against several pathological stimuli in laboratory rodents. At the mitochondrial level, protection promoted by CR in the brain and liver is related to higher calcium uptake rates and capacities, avoiding Ca2+-induced mitochondrial permeability transition. Dietary restriction has also been shown to increase kidney resistance against damaging stimuli such as ischemia/reperfusion, but if these effects are related to similar mitochondrial adaptations had not yet been uncovered. Here, we characterized changes in mitochondrial function in response to six months of CR in rats, measuring bioenergetic parameters, redox balance and calcium homeostasis. CR promoted an increase in mitochondrial oxygen consumption rates under non-phosphorylating and uncoupled conditions. While CR prevents mitochondrial reactive oxygen species production in many tissues, in kidney we found that mitochondrial H2O2 release was enhanced, although levels of carbonylated proteins and methionine sulfoxide were unchanged. Surprisingly, and opposite to the effects observed in brain and liver, mitochondria from CR animals are more prone to Ca2+-induced mitochondrial permeability transition. CR mitochondria also displayed higher calcium uptake rates, which were not accompanied by changes in calcium efflux rates, nor related to altered inner mitochondrial membrane potentials or the amounts of the mitochondrial calcium uniporter (MCU). Instead, increased mitochondrial calcium uptake rates in CR kidneys correlate with a loss of MICU2, an MCU modulator. Interestingly, MICU2 is also modulated by CR in liver, suggesting it has a broader diet-sensitive regulatory role controlling mitochondrial calcium homeostasis. Together, our results highlight the organ-specific bioenergetic, redox, and ionic transport effects of CR. Specifically, we describe the regulation of the expression of MICU2 and its effects on mitochondrial calcium transport as a novel and interesting aspect of the metabolic responses to dietary interventions.

Physiological and Pathophysiological Roles of Mitochondrial Na+-Ca2+ Exchanger, NCLX, in Hearts

It has been over 10 years since SLC24A6/SLC8B1, coding the Na+/Ca2+/Li+ exchanger (NCLX), was identified as the gene responsible for mitochondrial Na+-Ca2+ exchange, a major Ca2+ efflux system in cardiac mitochondria. This molecular identification enabled us to determine structure–function relationships, as well as physiological/pathophysiological contributions, and our understandings have dramatically increased. In this review, we provide an overview of the recent achievements in relation to NCLX, focusing especially on its heart-specific characteristics, biophysical properties, and spatial distribution in cardiomyocytes, as well as in cardiac mitochondria. In addition, we discuss the roles of NCLX in cardiac functions under physiological and pathophysiological conditions—the generation of rhythmicity, the energy metabolism, the production of reactive oxygen species, and the opening of mitochondrial permeability transition pores.

Enhanced resistance to Ca2+-induced mitochondrial permeability transition in the long-lived red-footed tortoise Chelonoidis carbonaria

The interaction between supraphysiological cytosolic Ca2+ levels and mitochondrial redox imbalance mediates the mitochondrial permeability transition (MPT). MPT is involved in cell death, diseases, and aging. This study compared the liver mitochondrial Ca2+ retention capacity and oxygen consumption in the long-lived red-footed tortoise (Chelonoidis carbonaria) to the rat as a reference standard. Mitochondrial Ca2+ retention capacity, a quantitative measure of MPT sensitivity, was remarkably higher in tortoises than rats. This difference was minimized in the presence of the MPT inhibitors, ADP and cyclosporine A. However, the Ca2+ retention capacities of tortoise and rat liver mitochondria were similar when both MPT inhibitors were present simultaneously. NADH-linked phosphorylating respiration rates of tortoise liver mitochondria represented only 30% of the maximal electron transport system capacity, indicating a limitation imposed by the phosphorylation system. These results suggested underlying differences in putative MPT structural components (e.g. ATP synthase, adenine nucleotide translocase (ANT), and cyclophilin D) between tortoises and rats. Indeed, in tortoise mitochondria, titrations of inhibitors of the oxidative phosphorylation components revealed a higher limitation of ANT. Furthermore, cyclophilin D activity was approximately 70% lower in tortoises than in rats. Investigation of critical properties of mitochondrial redox control that affect MPT demonstrated that tortoise and rat liver mitochondria exhibited similar rates of H2O2 release and glutathione redox status. Overall, our findings suggest that constraints imposed by ANT and cyclophilin D, putative components or regulators of the MPT pore, are associated with the enhanced resistance to Ca2+-induced MPT in tortoises.

Holographic imaging of mitochondrial optical density in living cells reveals that the Mitochondrial Permeability Transition is a two-stage process

Mitochondrial permeability transition is caused by the opening of the Cyclosporin A (CSA) dependent calcium-induced large pore, known as the Permeability Transition Pore (PTP). PTP activation is believed to be a central event in stress-induced cell death. However, the molecular details of PTP opening remain incompletely understood. PTP opening makes mitochondrial inner membrane permeable to the molecules up to 1.5 kDa in size. Solute equilibration with the media in combination with swelling due to the PTP opening make mitochondria optically transparent, a phenomenon that has been widely used as a bona fide "light-scattering" PTP detection method in isolated mitochondria. Here, we utilized holographic microscopy imaging to monitor mitochondrial optical density changes that occur during solute equilibration between matrix and cytoplasm and thus enabled us to assess PTP induction in living cells. This approach relies on label-free, real-time mitochondrial visualization due to refractive index (RI) differences between the mitochondrial matrix and cytoplasm in the intact cells. PTP activation was detected as the decrease in mitochondrial RI. These measurements were done in parallel with measurements of the mitochondrial membrane potential, using the fluorescent probe TMRM. In intact HAP 1 cells, we found that calcium stress caused CSA-sensitive depolarization of the mitochondrial inner membrane. Unexpectedly, high-conductance PTP did not occur until after nearly complete mitochondrial membrane depolarization. In cells lacking c and δ subunits of the ATP synthase, we observed calcium-induced and CSA-sensitive depolarization but not high-conductance PTP. We demonstrate that holographic imaging is a powerful novel tool with unique capabilities that allow measurement of PTP in living cells with high temporal and spatial resolution. We conclude that contrary to the widely accepted view, in living cells, high-conductance PTP is not the cause of calcium-induced membrane depolarization. Further, we provide direct evidence that ATP synthase is essential for high-conductance PTP, but not for calcium-induced CSA-sensitive membrane depolarization. We propose that PTP activation occurs as a two-phase process, where the first phase of the initial membrane depolarization is followed by the second phase of large pore opening that results in high-amplitude membrane permeabilization.