Physical restraint induces conditioned place aversion and region-specific c-Fos activation in mice

Linking environmental contexts with stressful experiences is critical for engaging adaptive responses necessary to avoid future threats. Yet, active context-dependent avoidance remains poorly understood. Here, we establish a restraint-induced conditioned place aversion (CPA) paradigm to examine how an acute physiological stressor acquires negative motivational value through contextual association. We found that mice repeatedly exposed to physical restraint in a contextually distinguishable chamber later avoid that location, demonstrating that restraint stress can drive learned aversion in the absence of continued exposure. To identify potential neuronal correlates underlying this learned association, we quantified c-Fos expression in several areas implicated in aversive motivation, emotional salience, and contextual encoding. We found that restraint within the context of the CPA paradigm was associated with increased c-Fos in the nucleus accumbens (NAc) and basolateral amygdala (BLA) while c-Fos expression increased in the ventral hippocampus in response to exposure to the contextual cues alone. These findings reveal region-specific activation in response to restraint stress and associated contextual cues. By connecting classical stress models and associative learning, this work provides a potential platform for further investigation of the neural mechanisms underlying stress-related negative affect and avoidance behaviors.