Architectonics of GABAergic inhibitory network in the sensorimotor area of the rat neocortex in the early postnatal period under normal conditions and after acute perinatal hypoxia

Abstract

The distribution of GABAergic interneurons as well as terminal and synaptic networks in different layers of the rat sensorimotor neocortex were studied at different stages of the postnatal period under normal conditions and after exposure to perinatal hypoxia. In control animals, the architectonics of the inhibitory network in different layers of the sensorimotor neocortex was shown to display distinctive features at different stages of the postnatal development. At early postnatal stages, a significant portion of neurons in layers II–V are immunopositive for GAD-67, indicative of a high level of GABA expression, however, GABA transmission is extremely weak, thus supporting the presence in the neuropil of only sporadic GABAergic terminals and synapses. By the juvenile age, a dramatic drop in the number of GABAergic neurons and an increase in the density of the network of GABA-immunopositive processes and synaptic structures occur in the neuropil, suggesting a considerable increase in GABA transmission. A higher level of GABA transmission is revealed in layers IV and V, persisting over the prepubertal period. Our results demonstrate that acute perinatal hypoxia affects the state of the inhibitory GABAergic network in the rat sensorimotor neocortex during the postnatal period. GABA expression and transmission were shown to change virtually in all layers.