A new paradigm of learned cooperation reveals extensive social coordination and specific cortical activation in mice

Cooperation is a social behavior crucial for the survival of many species, including humans. Several experimental paradigms have been established to study cooperative behavior and related neural activity in different animal species. Although mice exhibit limited cooperative capacity in some behavioral paradigms, it is still interesting to explore their cooperative behavior and the underlying neural mechanisms. Here, we developed a new paradigm for training and testing cooperative behavior in mice based on coordinated lever-pressing and analyzed social interactions between the animals during cooperation. We observed extensive social contact and waiting behavior in cooperating animals, with the number of such events positively correlated with the success of cooperation. Using c-Fos immunostaining and a high-speed volumetric imaging with synchronized on-the-fly scan and readout (VISoR) system, we further mapped whole-brain neuronal activity trace following cooperation. Significantly higher levels of c-Fos expression were observed in cortical areas including the frontal pole, motor cortex, anterior cingulate area, and prelimbic area. These observations highlight social interaction and coordination in cooperative behavior and provide clues for further study of the underlying neural circuitry mechanisms.

Automated summary

Cooperation is a vital social behavior for survival, and a new paradigm was developed to train and test cooperative behavior in mice. The study found extensive social contact and waiting behavior, which were positively correlated with the success of cooperation. Using c-Fos immunostaining and high-speed volumetric imaging, the researchers identified increased neuronal activity in cortical areas during cooperation, providing insights into the underlying neural circuitry mechanisms.