safranine-t and 5-5--6-6--tetrachloro-1-1--3-3--tetraethylbenzimidazolocarbocyanine

Mitochondria are considered as the main source of reactive oxygen species (ROS) in the cell. For this reason, they have been recognized as a source of various pathological conditions as well as aging. Chronic increase in the rate of ROS production is responsible for the accumulation of ROS-associated damages in DNA, proteins, and lipids, and may result in progressive cell dysfunctions and, in a consequence, apoptosis, increasing the overall probability of an organism's pathological conditions. The superoxide anion is the main undesired by-product of mitochondrial oxidative phosphorylation. Its production is triggered by a leak of electrons from the mitochondrial respiratory chain and the reaction of these electrons with O(2). Superoxide dismutase (MnSOD, SOD2) from the mitochondrial matrix as well as superoxide dismutase (Cu/ZnSOD, SOD1) present in small amounts in the mitochondrial intramembrane space, convert superoxide anion to hydrogen peroxide, which can be then converted by catalase to harmless H(2)O. In this chapter, we describe a relation between mitochondrial membrane potential and the rate of ROS formation. We present different methods applicable for isolated mitochondria or intact cells. We also present experiments demonstrating that a magnitude and a direction (increase or decrease) of a change in mitochondrial ROS production depends on the metabolic state of this organelle.

Topics: Animals; Benzimidazoles; Brain; Calcium; Carbocyanines; Carcinoma, Ehrlich Tumor; Cell Fractionation; Cell Line, Tumor; Electron Transport; Fibroblasts; HeLa Cells; Humans; Hydrogen Peroxide; Membrane Potential, Mitochondrial; Mice; Microscopy, Confocal; Mitochondria; Oxygen Consumption; Phenazines; Reactive Oxygen Species; Superoxides

Proximal tubules develop a severe energetic deficit during hypoxia-reoxygenation (H/R) that previous studies using fluorescent potentiometric probes have suggested is characterized by sustained, partial mitochondrial deenergization. To validate the primary occurrence of mitochondrial deenergization in the process, optimize approaches for estimating changes in mitochondrial membrane potential (DeltaPsim) in the system, and clarify the mechanisms for the defect, we further investigated the behavior of 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazocarbocyanine iodide (JC-1) in these cells and introduce a more dynamic and quantitative approach employing safranin O for use with the tubule system. Although use of JC-1 can be complicated by decreases in the plasma membrane potential that limit cellular uptake of JC-1 and such behavior was demonstrated in ouabain-treated tubules, changes in DeltaPsim entirely accounted for the decreases in the formation of red fluorescent JC-1 aggregates and in the ratio of red/green fluorescence observed after H/R. The red JC-1 aggregates did not readily dissociate when tubules were deenergized after JC-1 uptake, making it unsuitable for dynamic studies of energization. Safranin O uptake by digitonin-permeabilized tubules required very small numbers of tubules, permitted measurements of DeltaPsim for relatively prolonged periods after the end of the experimental maneuvers, was rapidly reversible during deenergization, and allowed for direct assessment of both substrate-dependent, electron transport-mediated DeltaPsim, and ATP hydrolysis-supported DeltaPsim. Both types of energization measured using safranin O in tubules permeabilized after H/R were impaired, but combining substrates and ATP substantially restored DeltaPsim.

Topics: Acute Kidney Injury; Adenosine Triphosphate; Animals; Benzimidazoles; Carbocyanines; Carbonyl Cyanide p-Trifluoromethoxyphenylhydrazone; Cell Membrane Permeability; Coloring Agents; Energy Metabolism; Enzyme Inhibitors; Female; Fluorescent Dyes; Hypoxia; Ionophores; Kidney Tubules, Proximal; Membrane Potentials; Mitochondria; Ouabain; Phenazines; Proton-Translocating ATPases; Rabbits