A neuropeptide S receptor variant associated with overinterpretation of fear reactions: a potential neurogenetic basis for catastrophizing.

Neuropeptide S (NPS) is a recently discovered G protein-coupled receptor ligand that modulates fear-like behaviors in rodents. A frequent A>T single-nucleotide polymorphism in the human NPS receptor gene NPSR1 confers a 10-fold higher efficacy of NPS signaling in vitro and has been linked with panic disorder (PD). We here report data from a classical fear-conditioning paradigm in healthy normal volunteers, in which carriers of the NPSR1 T allele evaluated their fear reactions to conditioned stimuli (CSs) as more pronounced than AA homozygous participants, although they did not show elevated peripheral-physiological conditioned responses (skin conductance responses-SCRs). T carriers also exhibited stronger CS-evoked brain activity in the rostral dorsomedial prefrontal cortex (dmPFC), an area that supports the explicit, conscious appraisal of threat stimuli. By contrast, more caudally situated mid-dmPFC, which has previously been associated with the generation of SCRs, showed no elevated response. Moreover, rostral dmPFC activation was correlated with participants' fear evaluations, further strengthening the link of this activation to increased individual fear appraisal. Our data suggest a genetic and neuroanatomical substrate for catastrophizing overinterpretations of fear reactions and provide a mechanistic explanation for the association between the NPSR1 T allele and PD.

Empirical support for an involvement of the mesostriatal dopamine system in human fear extinction.

Exposure therapy for anxiety disorders relies on the principle of confronting a patient with the triggers of his fears, allowing him to make the unexpected safety experience that his fears are unfounded and resulting in the extinction of fear responses. In the laboratory, fear extinction is modeled by repeatedly presenting a fear-conditioned stimulus (CS) in the absence of the aversive unconditioned stimulus (UCS) to which it had previously been associated. Classical associative learning theory considers extinction to be driven by an aversive prediction error signal that expresses the expectation violation when not receiving an expected UCS and establishes a prediction of CS non-occurrence. Insufficiencies of this account in explaining various extinction-related phenomena could be resolved by assuming that extinction is an opponent appetitive-like learning process that would be mediated by the mesostriatal dopamine (DA) system. In accordance with this idea, we find that a functional polymorphism in the DA transporter gene, DAT1, which is predominantly expressed in the striatum, significantly affects extinction learning rates. Carriers of the 9-repeat (9R) allele, thought to confer enhanced phasic DA release, had higher learning rates. Further, functional magnetic resonance imaging revealed stronger hemodynamic appetitive prediction error signals in the ventral striatum in 9R carriers. Our results provide a first hint that extinction learning might indeed be conceptualized as an appetitive-like learning process and suggest DA as a new candidate neurotransmitter for human fear extinction. They open up perspectives for neurobiological therapy augmentation.