Formation of Palmitic Acid/Ca<sup>2+</sup>Complexes in the Mitochondrial Membrane: A Possible Role in the Cyclosporin-Insensitive Permeability Transition

Mironova, Galina D.; Gritsenko, E. N.; Gateau-Roesch, Odile; Levrat, Christiane; Агафонов, А. В.; Belosludtsev, Konstantin N.; Muntean, Daniela-Lucia; Dubois, Marc-Jacques; Ovize, Michel

doi:10.1023/b:jobb.0000023620.42653.b7

Cited by 39 publications

(17 citation statements)

References 29 publications

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“…On the other hand, in the absence of P i and other triggers of the Ca 2+ dependent pore, palmitic acid (and other long chain saturated fatty acids) were recently found to induce opening of a pore insensitive to CsA [13 15]. And we have shown that this is accompanied by recovery of ∆ψ on the inner mitochondrial membrane practically to the ini tial level [15]. Thus, the palmitate induced pore is short living and can close spontaneously [13].…”

mentioning

confidence: 62%

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

Belosludtsev

Belosludtseva

Mironova

2005

Biochemistry (Moscow)

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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.

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mentioning

confidence: 62%

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

Belosludtsev

Belosludtseva

Mironova

2005

Biochemistry (Moscow)

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“…It is known that lipid pores can heal spontaneously [46]. Earlier, we showed that in sucrose/mannitol medium, formation of palmitate/Ca 2+ -induced pores in mitochondria was accompanied by a drop in membrane potential followed by gradual recovery to nearly the initial level [7]. However, mitochondria did not restore their volume, which would require removal of impermeant osmotic agents (sucrose and mannitol) from the mitochondrial matrix.…”

Section: Discussionmentioning

confidence: 98%

“…Fatty acids are substrates for mitochondrial respiration, uncouplers of oxidative phosphorylation, inducers of the mitochondrial permeability transition (MPT) pore and pro-apoptotic agents [1–5]. In the presence of Ca 2+ , long-chain saturated fatty acids also open a cyclosporin A (CsA)-insensitive pore in the mitochondrial inner membrane [6, 7]. Palmitate/Ca 2+ also induces pores in erythrocyte membranes, artificial lipid vesicles, and black lipid membranes [7–11].…”

Section: Introductionmentioning

confidence: 99%

“…In the presence of Ca 2+ , long-chain saturated fatty acids also open a cyclosporin A (CsA)-insensitive pore in the mitochondrial inner membrane [6, 7]. Palmitate/Ca 2+ also induces pores in erythrocyte membranes, artificial lipid vesicles, and black lipid membranes [7–11]. These findings indicate that the fatty acid/Ca 2+ -induced pore is lipid in nature.…”

Section: Introductionmentioning

confidence: 99%

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Effect of surface-potential modulators on the opening of lipid pores in liposomal and mitochondrial inner membranes induced by palmitate and calcium ions

Belosludtsev

Belosludtseva

Агафонов

et al. 2015

Biochimica et Biophysica Acta (BBA) - Biomembranes

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The effect of surface-potential modulators on palmitate/Ca2+-induced formation of lipid pores was studied in liposomal and inner mitochondrial membranes. Pore formation was monitored by sulforhodamine B release from liposomes and swelling of mitochondria. ζ-potential in liposomes was determined from electrophoretic mobility. Replacement of sucrose as the osmotic agent with KCl decreased negative ζ-potential in liposomes and increased resistance of both mitochondria and liposomes to the pore inducers, palmitic acid, and Ca2+. Micromolar Mg2+ also inhibited palmitate/Ca2+-induced permeabilization of liposomes. The rate of palmitate/Ca2+-induced, cyclosporin A-insensitive swelling of mitochondria increased 22% upon increasing pH from 7.0 to 7.8. At below the critical micelle concentration, the cationic detergent cetyltrimethylammonium bromide (10 μM) and the anionic surfactant sodium dodecylsulfate (10–50 μM) made the ζ-potential less and more negative, respectively, and inhibited and stimulated opening of mitochondrial palmitate/Ca2+-induced lipid pores. Taken together, the findings indicate that surface potential regulates palmitate/Ca2+-induced lipid pore opening.

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“…Long-chain fatty acids that are routinely present in plasma of normal individuals were shown to have cytotoxic effects at high concentrations, impair ATP generation, uncouple OXPHOS, inhibit the respiratory chain, depolarize mitochondria by their protonophoric properties, induce oxidative stress, and have permeability transition. [44][45][46][47][48][49] Medium-chain fatty acid effects on mitochondrial functions are less studied, but may similarly affect mitochondrial respiration and disturb the translocation of ADP in mitochondria. 50 Therefore, it is feasible that the fatty acids that accumulate in tissues of patients with MCAD and LCHAD deficiencies (Table 3) may similarly induce cellular toxicity.…”

Section: Disruption Of Mitochondrial Homeostasis In Mcad and Lchad Dementioning

confidence: 99%

Mechanistic Bases of Neurotoxicity Provoked by Fatty Acids Accumulating in MCAD and LCHAD Deficiencies

Amaral

Cecatto

Silva

et al. 2017

Journal of Inborn Errors of Metabolism and Screening

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Fatty acid oxidation defects (FAODs) are inherited metabolic disorders caused by deficiency of specific enzyme activities or transport proteins involved in the mitochondrial catabolism of fatty acids. Medium-chain fatty acyl-CoA dehydrogenase (MCAD) and long-chain 3-hydroxyacyl-CoA dehydrogenase (LCHAD) deficiencies are relatively common FAOD biochemically characterized by tissue accumulation of medium-chain fatty acids and long-chain 3-hydroxy fatty acids and their carnitine derivatives, respectively. Patients with MCAD deficiency usually have episodic encephalopathic crises and liver biochemical alterations especially during crises of metabolic decompensation, whereas patients with LCHAD deficiency present severe hepatopathy, cardiomyopathy, and acute and/or progressive encephalopathy. Although neurological symptoms are common features, the underlying mechanisms responsible for the brain damage in these disorders are still under debate. In this context, energy deficiency due to defective fatty acid catabolism and hypoglycemia/hypoketonemia has been postulated to contribute to the pathophysiology of MCAD and LCHAD deficiencies. However, since energetic substrate supplementation is not able to reverse or prevent symptomatology in some patients, it is presumed that other pathogenetic mechanisms are implicated. Since worsening of clinical symptoms during crises is accompanied by significant increases in the concentrations of the accumulating fatty acids, it is conceivable that these compounds may be potentially neurotoxic. We will briefly summarize the current knowledge obtained from patients with these disorders, as well as from animal studies demonstrating deleterious effects of the major fatty acids accumulating in MCAD and LCHAD deficiencies, indicating that disruption of mitochondrial energy, redox, and calcium homeostasis is involved in the pathophysiology of the cerebral damage in these diseases. It is presumed that these findings based on the mechanistic toxic effects of fatty acids may offer new therapeutic perspectives for patients affected by these disorders.

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Formation of Palmitic Acid/Ca²⁺Complexes in the Mitochondrial Membrane: A Possible Role in the Cyclosporin-Insensitive Permeability Transition

Cited by 39 publications

References 29 publications

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

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

Effect of surface-potential modulators on the opening of lipid pores in liposomal and mitochondrial inner membranes induced by palmitate and calcium ions

Mechanistic Bases of Neurotoxicity Provoked by Fatty Acids Accumulating in MCAD and LCHAD Deficiencies

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Formation of Palmitic Acid/Ca2+Complexes in the Mitochondrial Membrane: A Possible Role in the Cyclosporin-Insensitive Permeability Transition

Cited by 39 publications

References 29 publications

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

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

Effect of surface-potential modulators on the opening of lipid pores in liposomal and mitochondrial inner membranes induced by palmitate and calcium ions

Mechanistic Bases of Neurotoxicity Provoked by Fatty Acids Accumulating in MCAD and LCHAD Deficiencies

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Formation of Palmitic Acid/Ca²⁺Complexes in the Mitochondrial Membrane: A Possible Role in the Cyclosporin-Insensitive Permeability Transition