Cocaine, via ΔFosB, remodels gene expression and excitability in ventral hippocampus
Ventral hippocampus (vHPC) CA1 pyramidal neurons send glutamatergic projections to nucleus accumbens (NAc), and this vHPC-NAc circuit mediates cocaine seeking and reward, but it is unclear whether vHPC-NAc neuron properties are modulated by cocaine exposure to drive subsequent behavior. The immediate early gene transcription factor {Delta}FosB is induced throughout the brain by cocaine and is critical for cocaine seeking, but it's function in vHPC-NAc neurons is not understood. We now show that circuit-specific knockout of {Delta}FosB in vHPC-NAc neurons impaired cocaine reward expression and forced abstinence-induced seeking. We also found that vHPC-NAc excitability was decreased by experimenter-administered repeated cocaine and cocaine self-administration, and this cocaine-induced excitability decrease was mediated by {Delta}FosB expression. To uncover the mechanism of this change in circuit function, we used circuit-specific translating ribosomal affinity purification (TRAP) to assess cocaine-induced, {Delta}FosB-dependent changes in gene expression in vHPC-NAc. We found that cocaine causes a {Delta}FosB-dependent increase in the expression of calreticulin, an ER-resident calcium-buffering protein. Calreticulin expression mediated vHPC-NAc excitability and was necessary for cocaine reward. These findings uncover a novel, non-canonical mechanism by which cocaine increases calreticulin in vHPC leading to decreased vHPC-NAc excitability and drives cocaine seeking and reward.