Взаимодействие механизмов угнетения квантового выделения ацетилхолина при активации ваниллоидных (TRPV1) и пуриновых рецепторов в нервно-мышечном синапсе мыши

Abstract

The main goal of the study was to analyze the relationship between the signaling pathways of the regulation of acetylcholine (ACh) quantal release in the peripheral synapse triggered by the activation of vanilloid (TRPV1) and purine receptors. In electrophysiological experiments carried out at the neuromuscular synapses of the m. Levator Auris Longus, it was found that the frequency of miniature endplate potentials (mEPPs) and the quantal content of endplate potentials (EPPs) decrease in the presence of TRPV1 agonist capsaicin. This effect was completely reversed by SB366791, a specific competitive antagonist of TRPV1 receptors. ATP, like capsaicin, decreased the frequency of mEPPs and the EPP quantal content. Against the background of the TRPV1 antagonist, the inhibitory effect of ATP on ACh secretion was realized in full. At the same time, against the background of TRPV1 channels activation by capsaicin, the effect of ATP on both spontaneous and evoked ACh release was absent. It was suggested that the mechanisms of action of ATP and capsaicin may be associated with a change in Ca2+ entry into the nerve ending. To test this hypothesis, experiments were carried out to assess the changes in the presynaptic calcium level (Ca2+ transient) using a fluorescent calcium dye upon nerve stimulation. The amplitude of the calcium transient did not change either with the application of ATP or with the addition of capsaicin. Thus, in the neuromuscular synapse of mammals, along with purinergic pathway of ACh secretion regulation, there is also a mechanism of neurosecretion modulation mediated by the activation of TRPV1 channels. The triggering of these mechanisms leads to the suppression of the processes of both spontaneous and evoked release of ACh quanta from the motor nerve endings. It was demonstrated that both pathways of regulation are not accompanied by a change in the Ca2+ transient, but have a common link of regulation of the quantal neurosecretion.