DOI: 10.1073/pnas.2517987123 ISSN: 0027-8424

Neuropeptide signaling and the blood–brain barrier generate a persistent stress-induced internal state in Drosophila

Abdalla G. Alia, Xinyue Hu, Yuzhe Gu, Janviere Yau, Guangnan Tian, Julie L. Semmelhack, Kokoro Saito, Hiromu Tanimoto, Koki Tsuyuzaki, Shintaro Naganos, Tomoyuki Miyashita, Minoru Saitoe, Yukinori Hirano

Although fear conditioning has elucidated cue-evoked acute fear responses, the mechanisms by which stress experiences induce generalized internal states linked to anxiety or phobia are poorly understood. Here, we report that robust stress induces a persistent behavioral change characterized by avoidance of a confined space, claustrophobia-like behavior (CLB) in Drosophila . Unlike aversive memory formation, the development of CLB does not require dopamine receptors. Our neuronal screening determined that neuropeptide signaling via Allatostatin-A inactivates the downstream neurons via its receptor AstA-R1, causally inducing CLB. Moreover, gene expression profiling of individual fly heads revealed that innate immune response activation in the blood–brain barrier is involved in CLB. Our data demonstrate that stress-induced persistent behavioral change would not be related to a canonical mechanism of aversive memory formation, rather involves neuropeptidergic signaling and the blood–brain barrier, providing the mechanism determining internal states which persistently change into a phobia-like mode.

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