GABAergic circuits reflect different requirements for emergent perception in postnatal mouse neocortex

Abstract

AbstractInformation transfer in the mammalian cerebral cortex is dependent on locally-projecting GABAergic interneuron circuits that are widely assumed to be uniform across neocortical areas. We demonstrate that this does not hold true during the highly dynamic period of postnatal life prior to the onset of active sensory exploration. During this time, a subset of interneuron defined by expression of the neuropeptide somatostatin differentially contribute to sensory-evoked activity in primary somatosensory and visual cortices. This functional divergence between the two areas is explained by differences in the composition of somatostatin interneuron subtypes and the transient circuits formed by these cells; the somatosensory circuit representing an adaptation to control early neonatal touch information. Understanding such area-dependent differences will promote our endeavours to understand the aetiology of developmental psychiatric disorders.Summary SentenceCortical circuits are adapted to the local information processing demands of the developing brain