Impact of Swimming Exercise Training on the Effects of Modulation of Mitochondrial Permeability Transition and NOS-1 Activation in Medullary Cardiovascular Neurons of Rats

Abstract

Physical inactivity can be considered one of the major risk factors related to cardiovascular diseases. There are reasons to believe that the positive effect of exercise training is, to a large extent, mediated by modulation of the nervous control of the circulation system. In our previous studies, we showed that modulation of mitochondrial permeability transition in medullary cardiovascular neurons significantly contributes to the hemodynamic reactions in both the norm and a number of pathological states. In this study, we examined in acute experiments on urethane-anesthetized rats the hemodynamic effects mediated by either modulation of mitochondrial permeability transition in medullary neurons, or activation of neuronal NO synthase (NOS-1) in these neuronal populations after preliminary moderate exercise training (everyday swimming sessions of increased duration carried out for four weeks). It was shown that, after exercise training had been completed, the effects of injections of an inductor of mitochondrial permeability transition pore (MPTP) opening, phenylarsine oxide (PAO, 0.5 to 1.5 nmol), into populations of cardiovascular neurons in the medullary autonomic nuclei (nucl. tractus solitarius and paramedian and lateral reticular nuclei) were less expressed, as compared with those in control (untrained) animals. The data obtained suggest that exercise training can exert a protective action on functional activity of medullary neurons due to the decreased sensitivity of MPTPs to their opening. Injections of an inhibitor of MPTP opening, melatonin (0.7 to 2.1 nmol), into populations of medullary neurons under study in trained rats induced a decrease in the systemic arterial pressure (SAP), in contrast to untrained animals demonstrating mostly hypertensive responses following injections of melatonin into the above nuclei. Injections of an activator of neuronal NO synthase (NOS-1), L-arginine, into the medullary nuclei of swimming-trained rats resulted in more expressed hemodynamic shifts than in control animals, which suggests an increase in the activity of neuronal NO synthase in medullary neurons of such animals.