Dynamic regulation of oxytocin neuronal circuits in the sequential processes of prosocial behavior in rodent models

The expression of positive social (i.e., prosocial) behavior is governed by a multitude of sensory and cognitive abilities to identify and recognize key features of potential social partners, elucidate social and individual status, and maintain appropriate behaviors. Oxytocin (OT) is a neuropeptide that has been implicated as a major player in regulating prosocial behavior, and much of its role in social situations has been uncovered. As social behavior inherently comprises sequential processes related to multimodal assessments of interactive features, a comprehensive approach to understanding the functions of OT in these prosocial behavior sequences is required. Here, the author discusses recent evidence illustrating the functioning of OT neural circuits in the processing of multimodal components of social behavior, including the detection/recognition of social cues via the olfactory bulb through olfactory cortices, evaluation of social features via the circuits of the paraventricular nucleus of the hypothalamus to the medial amygdala, and maintenance of prosocial behaviors via the circuits of the ventral tegmental area to the nucleus accumbens. A review of rodent studies with an emphasis on mice and rats is also provided to investigate the effects of OT in interaction with other neurotransmitters, such as serotonin and dopamine, to characterize the neuromodulatory mechanisms that mediate the sequences of prosocial engagements. The review further highlights OT function as a temporal dynamic of specific neural circuits.