Major depressive disorder is a severe psychiatric disorder that afflicts ~17% of the world population. Neuroimaging investigations of depressed patients have consistently reported the dysfunction of the basolateral amygdala in the pathophysiology of depression. However, how the BLA and related circuits are implicated in the pathogenesis of depression is poorly understood.
Here, we combined fiber photometry, immediate early gene expression (c‐fos), optogenetics, chemogenetics, behavioral analysis, and viral tracing techniques to provide multiple lines of evidence of how the BLA neurons mediate depressive‐like behavior.
We demonstrated that the aversive stimuli elevated the neuronal activity of the excitatory BLA neurons (BLA CAMKII neurons). Optogenetic activation of CAMKII neurons facilitates the induction of depressive‐like behavior while inhibition of these neurons alleviates the depressive‐like behavior. Next, we found that the chemogenetic inhibition of GABAergic neurons in the BLA (BLA GABA) increased the firing frequency of CAMKII neurons and mediates the depressive‐like phenotypes. Finally, through fiber photometry recording and chemogenetic manipulation, we proved that the activation of BLA GABA neurons inhibits BLA CAMKII neuronal activity and alleviates depressive‐like behavior in the mice.
Under normal conditions, BLA neurons are in a resting state and maintained the balance in inhibition/excitation. However, stress leads to the overactivity of BLA CAMKII neurons and mediates the depressive‐like phenotypes. Enhancing the inhibition in the BLA either through chemogenetic activation of BLA GABA neurons or direct inhibition of BLA CAMKII neurons alleviates depressive‐like behaviors.