Selective vulnerability of parvocellular oxytocin neurons in social dysfunction

Selective vulnerability offers a conceptual framework for understanding neurodegenerative disorders such as Parkinson's disease, where specific neuronal types are selectively affected and adjacent ones are spared. However, the applicability of this framework to neurodevelopmental disorders, particularly those characterized by atypical social behaviors, such as autism spectrum disorder, remains uncertain. Here we show that an embryonic disturbance, known to induce social dysfunction in male mice, preferentially impaired the gene expression crucial for neural functions in parvocellular oxytocin (OT) neurons-a subtype linked to social rewards-while neighboring cell types experienced a lesser impact. Chemogenetic stimulation of OT neurons at the neonatal stage ameliorated social deficits in early adulthood, concurrent with cell-type-specific sustained recovery of pivotal gene expression within parvocellular OT neurons. Collectively, our data shed light on the transcriptomic selective vulnerability within the hypothalamic social behavioral center and provide a potential therapeutic target through specific neonatal neurostimulation. The specific cell types affected in neurodevelopmental disorders remain elusive. Here, authors show a selective weakness of certain hypothalamic neurons in a mouse model of social dysfunction and explore its potential therapeutic intervention.