Aging- and Experimental Mitochondrial Dysfunction-Related Modifications of Energy Metabolism in Brainstem Neurons

Using a polarographic technique, we studied the peculiarities of energy metabolism in neurons of the rat brainstem structures related to normal physiological aging. Experiments were carried out under in vitro conditions on mitochondrial (MCh) suspensions prepared from the brainstem cells of young and old rats. In addition, we examined, using the same technique, the parameters of oxidative phosphorylation in analogous MCh suspension under conditions of experimental MCh dysfunction induced by single systemic injection of rotenone into young animals. In the case where we used a succinate + rotenone mixture as the substrate for oxidation, the intensity of ADP-stimulated respiration (V3) in preparations from brainstem neurons of old animals was significantly smaller (against the background of a decrease in the efficacy of respiration control, V3/V4). If a mixture glutamate + malate was used as the substrate for oxidation, the V3 and the efficacy of phosphorylation (ADP/O) decreased significantly. The experimental MCh dysfunction resulted in the lowering of practically all parameters of oxidation and phosphorylation under conditions of oxidation of glutamate + malate, as well as V3, V3/V4, and ADP/O, in the case where we used succinate + rotenone as the substrate for oxidation. Less expressed changes in the recorded indices upon oxidation of succinate + rotenone were indicative of activation of the succinate oxidase pathway; this preserved the electrotransport function of the respiratory chain in the MCh on a certain level and the ability of the latter to provide oxidative phosphorylation.