ABSTRACT
As the elements of local neuronal circuits, parvalbumin (PV)-containing interneurons in the basolateral nucleus (BL) of the amygdala play an important role in the amygdaloid functions of emotion, learning and memory. In order to investigate how the PV-containing interneurons in the BL are controlled, the synapses established on PV- containing interneurons in the BL of the rat amygdala were examined under immunoelectron microscopy using the double labeling methods with anti-PV and anti-dopamine (DA) antibodies for a reference of dopaminergic axon terminals. The results show that the PV immunoreactive (IR) neurons formed the synapses mainly on the dendritic structures from shafts of the dendrites to median and small dendritic branches. 68% of the synapses on the PV-IR profiles were formed by unlabeled axon terminals, and 32 % of them were formed by DA- (21 % ) and PV- (11 % )IR axon terminals. Majority of the synapses on the PV-IR neurons formed by unlabeled axon terminals were symmetric type, and only a small a mount of them were asymmetric that were observed between the PV-IR spines and unlabeled axon terminals and in the serial synapses in which an unlabeled axon terminal symmetrically contacted to another unlabeled axon terminal that, in turn, synapsed asymmetrically to the PV-IR dendritic profiles. The synapses formed between the PV-IR profiles and DA- or PV-IR axon terminals were exclusively symmetric. The present results suggest that the PV-containing interneurons in the BL of the rat amygdala were controlled by an inhibitory network formed by the symmetric synapses around them, among which the DA system was included.