Venkataramanappa, S.; Graf, J.; Haselmann, H.; Schuetz, D.; Storch, O.; Roemer, D.; Ashok-Kumar, P.; Blanck-Stein, N.; Mayer, C.; Holthoff, K.; Kirmse, K.; Abe, P.; Stumm, R.

Cortical inhibitory neurons (CIN) populate the neocortex and hippocampus by extensive tangential migration. This process is highly vulnerable to genetic and environmental disturbances and is linked to neuropsychiatric disorders. However, the mechanisms by which transient migratory abnormalities translate into persistent functional deficits remain poorly understood. Here, we utilized a conditional Cxcr4 knockout to investigate the consequences of disrupted migratory guidance - a feature of genetic schizophrenia models. This demonstrated that despite migrating in ectopic cortical layers, CIN quantitatively colonized the neocortex until birth, whereas limbic regions developed a permanent deficit in CIN numbers. Furthermore, CIN failed to populate the neocortical marginal zone, a transient reservoir for late-born CIN destined for superficial cortical layers. Consequently, the layering and molecular identities of CIN, as well as the synaptic connectivity and spontaneous activity of the neuronal network, were significantly altered in the early postnatal neocortex. Although abnormal CIN layering was gradually compensated before maturity, functional differences persisted, as evidenced by facilitated propagation of sensory stimuli between cortical areas. These results demonstrate that CIN migration is an instructive process critical for activity-driven early postnatal network maturation and CIN identity, thus providing a mechanistic link between migratory guidance and the integrity of mature circuits.