Due to increased global use, acute and chronic exposures to pyrethroid insecticides in humans are of clinical concern. Pyrethroids have a primary mode of action that involves interference with the sodium and calcium channels in excitable cells, which may include cardiac myocytes. Here, we investigated the possible cardiac toxicity of permethrin metabolites (METP), 3-phenoxy-benzyl alcohol (3PBA), 3-phenoxy-benzaldehyde (3PBALD), and 3-phenoxybenzoic acid (3PBACID). Plasma membrane fluidity, polarity, lipid, and protein oxidation were studied in isolated rat heart cells. Laurdan was chosen as probe to detect the lateral mobility and polarity of its environment and thus water penetration into the hydrophobic part of the bilayer, while 1,6-diphenyl-1,3,5-hexatriene permits to measure changes in fluidity in the inner part of the bilayer. Results show that METP can change membrane fluidity at different depths of the bilayer according to their partition coefficient. Consequently, 3PBA, at all concentration used, decreases membrane fluidity and polarity in the hydrophilic-hydrophobic region of the bilayer, and similar effect was observed with 20 μM 3PBALD or 10 or 20 μM 3 PBACID. Membrane dynamics in the hydrophobic core resulted decreased by 3PBALD, while it was increased by 20 μM 3PBACID. All METP increase protein and lipid oxidation, and the peroxidative lipid damage decreases with the type of METP produced during the transformation pathway from parent compound to 3PBACID. Consequently, 3PBA induced the highest lipid peroxidation, while 3PBACID was the stronger inducer of protein damage.
Exercise-induced changes in p66Shc-dependent signaling pathway are still not fully understood. The p66Shc protein is one of the key players in cell signaling, particularly in response to oxidative stress. Therefore, the aim of this study was to investigate the effect of prolonged swimming on the phosphorylation of p66Shc as well as the induction of mitochondrial and cellular oxidative stress in rat hearts. Male Wistar rats were divided into a sedentary control group and an exercise group. The exercised rats swam for 3 hours and were burdened with an additional 3% of their body weight. After the cessation of exercise, their hearts were removed immediately for experiments. The exercise protocol caused increased levels of the following oxidative stress parameters in cardiac cells: DNA damage, protein carbonyls, and lipid dienes. There was also increased phosphorylation of p66Shc without any alterations in Akt and extracellular signal-regulated kinases. Changes in the ferritin L levels and the L to H subunit ratio were also observed in the exercised hearts compared with the control hearts. Despite increased phosphorylation of p66Shc, no significant increase was observed in either mitochondrial H2O2 release or mitochondrial oxidative stress markers. Regardless of the changes in phosphorylation of p66Shc, the antioxidant enzyme activities (superoxide dismutase and catalase) and anti-apoptotic (Bcl2), and pro-apoptotic (Bax) protein levels were not affected by prolonged swimming. Further studies are required to investigate whether p66Shc phosphorylation is beneficial or detrimental to cardiac cells after exercise cessation.
New findings r What is the central question of this study?The central question was to establish whether decreased cholesterol content in heart mitochondria caused by prolonged swimming may provoke changes in their bioenergetics and affect resistance to CaCl 2 -induced mitochondrial swelling. r What is the main finding and its importance?The main finding is the indication that changes in the cholesterol pool in heart mitochondria induced by swimming exercise are related to an increase in resistance to CaCl 2 -induced swelling, probably by remodelling of lipid microdomains, and are not deleterious for mitochondrial bioenergetics. These findings may contribute to a more complete understanding of the defense system that may prevent mitochondrial degradation during exercise and the protective system of cardiac cell defense in stress conditions. The significance of the reduction of the cholesterol pool in heart mitochondria after exercise is still unknown. Recently, published data have suggested that cholesterol may influence the components of mitochondrial contact site and affect mitochondrial swelling. Therefore, the aim of this study was to determine whether the decreased cholesterol content in heart mitochondria caused by prolonged swimming may provoke changes in their bioenergetics and result in an increased resistance to calcium chloride-induced mitochondrial swelling. Male Wistar rats were divided into a sedentary control group and an exercise group. The rats exercised for 3 h, burdened with an additional 3% of their body weight. Their hearts were removed immediately after completing the exercise. The left ventricle was divided and used for experiments. Mitochondrial cholesterol content, membrane fluidity and mitochondrial bioenergetics were measured in the control and exercised rat heart mitochondria. To assess whether mitochondrial modifications are linked to disruption of lipid microdomains, methyl-β-cyclodextrin, a well-known lipid microdomain-disrupting agent and cholesterol chelator, was applied to the mitochondria of the control group. Cholesterol depletion, increased membrane fluidity and increased resistance to calcium chloride-induced swelling were observed in postexercise heart crude mitochondrial fraction. Similar results were achieved in control mitochondria treated with 2% methyl-β-cyclodextrin. All of the mitochondrial bioenergetics parameters were similar between the groups.
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