Project Summary Anxiety disorders are highly prevalent, with diagnoses peaking during adolescence, creating a significant psychological and economic societal burden. Moreover, existing behavioral treatments to attenuate inappropriate fear responding in anxiety disorders have limited or no success for nearly half of the adolescent population. A critical barrier to developing treatments better suited for this group is a lack of knowledge about how key neural circuits related to fear acquisition and inhibition mature. The principal goal of this project is to identify the mechanisms underlying fear inhibition specifically as it manifests during adolescence. This project integrates adolescent behavioral models with cutting edge neural imaging and manipulation techniques to elucidate the yet unstudied mechanisms by which safety signals inhibit fear during adolescence. A ‘conditioned safety’ paradigm adapted for application during mouse adolescence is used to address key basic science questions about safety learning with far-reaching translational and clinical value. Through this paradigm, mice learn to utilize stimuli explicitly predicting the absence of an aversive outcome (i.e., ‘safety signals’) in service of attenuating fear responding. Research during the Mentored (K99) phase focused on the connection between the the ventral hippocampus (VH) and prelimbic cortex (PL), regions involved in the allocation and regulation of affective behaviors, and that undergo robust changes across adolescence. In-vivo calcium imaging (fiber photometry) was used to record and optogenetics to manipulate activity in VH-PL neurons in adolescent mice, elucidating a link between real-time dynamics of safety and fear behavior to fluctuations VH-PL signaling. Drawing from the literature and integrating preliminary data collected during the K99 phase led to the advancement of the central hypothesis that VH projections to PL interneurons promote safety behavior by producing a net inhibition of PL that is sustained throughout presentations of safety, but not fear signals, and that the heightened plasticity observed within VH and PL during adolescence provides a ‘sensitive window’ for enhanced efficacy of the conditioned inhibition of fear by safety signals. The goal of the Independent (R00) phase is to identify the PL interneuron targets of VH neurons and their relative activity during conditioned safety. Aim 1 will use a spectrally resolved fiber photometry system to record simultaneously from VH projections and select populations of PL interneurons. Aim 2 will use a Fos-activated (TRAP) viral-vector strategy to manipulate functional ensembles of PL interneurons to establish their contributions to the inhibition of fear. A foundation for accomplishing this research has been set through intensive training and discussion with an advisory panel of mentors, consultants, and collaborators with renowned expertise in adolescent development, fear learning, and circuit and cell-type ...