Rotenone Decreases Ischemia-Induced Injury by Inhibiting Mitochondrial Permeability Transition: A Study in Brain.

Mitochondria participate in many physiological and pathological processes in the cells, including cellular energy supply, regulation of calcium homeostasis, apoptosis, and ROS generation. Alterations of mitochondrial functions, especially the opening of mitochondrial permeability transition pore (mPTP) are the main mechanisms responsible for the ischemic brain damage. Recently, the inhibitors of the Complex I of mitochondrial respiratory chain emerged as promising suppressors of mitochondrial ROS generation and mPTP opening. Here we describe the assay that can be implemented easily to evaluate the protective effects of rotenone or other potential inhibitors of the Complex I of mitochondrial respiratory chain against acute ischemia-induced injuries in brain.

Comparison of Effects of Metformin, Phenformin, and Inhibitors of Mitochondrial Complex I on Mitochondrial Permeability Transition and Ischemic Brain Injury.

Damage to cerebral mitochondria, particularly opening of mitochondrial permeability transition pore (MPTP), is a key mechanism of ischemic brain injury, therefore, modulation of MPTP may be a potential target for a neuroprotective strategy in ischemic brain pathologies. The aim of this study was to investigate whether biguanides-metformin and phenformin as well as other inhibitors of Complex I of the mitochondrial electron transfer system may protect against ischemia-induced cell death in brain slice cultures by suppressing MPTP, and whether the effects of these inhibitors depend on the age of animals. Experiments were performed on brain slice cultures prepared from 5-7-day (premature) and 2-3-month old (adult) rat brains. In premature brain slice cultures, simulated ischemia (hypoxia plus deoxyglucose) induced necrosis whereas in adult rat brain slice cultures necrosis was induced by hypoxia alone and was suppressed by deoxyglucose. Phenformin prevented necrosis induced by simulated ischemia in premature and hypoxia-induced-in adult brain slices, whereas metformin was protective in adult brain slices cultures. In premature brain slices, necrosis was also prevented by Complex I inhibitors rotenone and amobarbital and by MPTP inhibitor cyclosporine A. The latter two inhibitors were protective in adult brain slices as well. Short-term exposure of cultured neurons to phenformin, metformin and rotenone prevented ionomycin-induced MPTP opening in intact cells. The data suggest that, depending on the age, phenformin and metformin may protect the brain against ischemic damage possibly by suppressing MPTP via inhibition of mitochondrial Complex I.

Protective effects of anthocyanins against brain ischemic damage.

Anthocyanins are considered as bioactive components of plant-based diets that provide protection against ischemic cardiovascular pathologies by mechanisms dependent on their antioxidant and reductive capacities. However, it is not clear whether similar anthocyanin-mediated mechanisms can provide protection against ischemia-induced brain mitochondrial injury and cell death. In this study, we compared effects of three cyanidin-3-glycosides - glucoside (Cy3G), galactoside (Cy3Gal) and rutinoside (Cy3R), with pelargonxidin-3-glucoside (Pg3G) and found that at 10-20 µM concentrations they have no direct effect on respiratory functions of mitochondria isolated from normal or ischemia-damaged rat brain slices. However, intravenous injection of Cy3Gal and Cy3G (0,025 mg/kg or 0,05 mg/kg what matches 10 µM or 20 µM respectively) but not Cy3R in rats protected against ischemia-induced caspase activation and necrotic cell death, and reduced infarct size in cerebral cortex and cerebellum. These effects correlated with cytochrome c reducing capacity of cyanidin-3-glycosides. In contrast, intravenous injection of 0,025 mg/kg Pg3G which has the lowest cytochrome c reducing capacity among investigated anthocyanins, had no effect on ischemia-induced caspase activation and necrosis but reduced brain infarct size whereas intravenous injection of 0,05 mg/kg of Pg3G slightly promoted necrosis in the brain. Our data suggest that reductive rather than antioxidant capacities of anthocyanins may be important components in providing protection against ischemic brain damage.

Data on effects of rotenone on calcium retention capacity, respiration and activities of respiratory chain complexes I and II in isolated rat brain mitochondria.

The data presented in this article are related to the research article entitled "Rotenone decreases ischemia-induced injury by inhibiting mitochondrial permeability transition in mature brains" (Rekuviene et al., 2017) [1]. Data in this article present the direct effects of rotenone on calcium retention capacity (CRC) in isolated normal cortex and cerebellum mitochondria, effects of rotenone intravenous infusion on leak and phosphorylating respiration rates of isolated cortex and cerebellum mitochondria, on activities of respiratory chain complexes I and II in freezed-thawed/sonicated cortex and cerebellum mitochondria after brain ischemia. In addition, detailed experimental procedures of isolation of brain mitochondria, measurements of CRC, respiration, activities of respiratory chain complexes and H2O2 generation in cortex and cerebellum mitochondria are described.

Rotenone decreases ischemia-induced injury by inhibiting mitochondrial permeability transition in mature brains.

The mitochondrial permeability transition pore (mPTP) is thought to be implicated in brain ischemia-induced cell death. Here we sought to determine whether complex I (CI) of the mitochondrial electron transfer system may be involved in regulation of mPTP opening during ischemia and whether a specific inhibitor of this complex - rotenone can protect against ischemia-induced cell death in an experimental model of total ischemia in adult rat brains. Anesthetized Wistar rats were administered a single injection of rotenone (0.01mg/kg) to the tail vein and brains were removed and subjected to 120min ischemia. We found that intravenous injection of rotenone 20min before ischemia increased resistance to Ca2+-induced mPTP opening and decreased production of reactive oxygen species (ROS) in mitochondria isolated from ischemia-damaged cortex and cerebellum. Rotenone administration before ischemia decreased infarct size in both brain regions (cortex and cerebellum). Rotenone added directly to normal, non-ischemic cortical or cerebellar mitochondria increased their resistance to Ca2+-induced mPTP opening at concentration which fully inhibited NAD-dependent mitochondrial respiration. Our data demonstrate that rotenone used intravenously may be protective against acute brain ischemia-induced injuries by inhibition of mPTP opening and ROS production. These findings suggest that CI of mitochondrial electron transfer system plays a role in mPTP regulation during cerebral ischemia in mature brains and that agents acting on CI activity may be clinically useful for stroke therapy.