Inhibition of spontaneous synchronous activity of hippocampal neurons by excitation of GABAergic neurons

The molecular mechanisms of the neuronal spontaneous synchronous activity (SSA) regulation by population of GABAergic neurons have been investigated in rat hippocampal culture. The neurons from this population contain Ca²⁺-permeable KA receptors on the presynaptic membrane. Using image analysis, confocal microscopy and immunocytochemistry, we identified by the shape of Ca²⁺ signal the population of GABAergic neurons with unique charachteristics allowing these neurons to control SSA. The SSA in a neuronal network was suppressed by the KA-receptor mediated [Ca²⁺]i increase in neurons of this population. Agonists of GluR5/GluK1-containing KA receptors (domoic acid (DA), SYM2081, and ATPA) evoked a fast high-amplitude Ca²⁺ signal without desensitization only in this population of neurons. This fact points to Ca²⁺ permeability of KA receptors in these neurons. The GABA(A) receptor antagonist bicuculline increased the activity of AMPA but not KA receptors of these neurons, indicating presynaptical localization of KA receptors. Depolarization of cells induced by KCl (unlike bicuculline-induced depolarization) increased the activity of AMPA and KA receptors twofold, which points to the dependence of the activity on depolarization. A tenfold increase of the SSA frequency in neurons of this population caused an increase in the basal [Ca²⁺]i level, which was accompanied by inhibition of SSA in another numerous population of neurons, suggesting that an increased GABAergic inhibition takes place. Prolonged high-frequency oscillations causes a global [Ca²⁺]i increase in the neurons of this population and their subsequent death. Thus, KA receptors in the population of fast GABAergic neurons may implement a negative feedback under hyperexcitation by glutamate enhancing GABA release due to the fast and prolonged [Ca²⁺]i increase. It has been shown that this mechanism can be used to suppress hyperactivation of a certain population of neurons under high-frequency SSA and ischemia. It is obvious that selective death of inhibitory neurons from this population may lead to hyperexcitability of certain brain regions.