PT - JOURNAL ARTICLE AU - Choi, Min-Kyeung AU - Cook, Alex AU - Mungikar, Kanak AU - Eachus, Helen AU - Tochwin, Anna AU - Linke, Matthias AU - Gerber, Susanne AU - Ryu, Soojin TI - Lifelong molecular consequences of high Glucocorticoids exposure during development AID - 10.1101/2023.02.13.528363 DP - 2024 Jan 01 TA - bioRxiv PG - 2023.02.13.528363 4099 - http://biorxiv.org/content/early/2024/01/09/2023.02.13.528363.short 4100 - http://biorxiv.org/content/early/2024/01/09/2023.02.13.528363.full AB - Early life stress (ELS) is one of the strongest risk factors for developing psychiatric disorders in humans. As conserved key stress hormones of vertebrates, glucocorticoids (GCs) are thought to play an important role in mediating the effects of ELS exposure in shaping adult phenotypes. In this process, early exposure to high level of GCs may induce molecular changes that alter developmental trajectory of an animal and primes differential adult responses. However, comprehensive characterization of identities of molecules that are targeted by developmental GC exposure is currently lacking. In our study, we describe lifelong molecular consequences of high level of developmental GC exposure using an optogenetic zebrafish model. First, we developed a new double-hit stress model using zebrafish by combining exposure to a high endogenous GC level during development and acute adulthood stress exposure. Our results establish that similar to ELS-exposed humans and rodents, developmental GC exposed zebrafish model shows altered behavior and stress hypersensitivity in adulthood. Second, we generated time-series gene expression profiles of the brains in larvae, in adult, and upon stress exposure to identify molecular alterations induced by high developmental GC exposure at different developmental stages. Third, we identify a set of GC-primed genes that show altered expression upon acute stress exposure only in animals exposed to a high developmental GC. Interestingly, our datasets of GC primed genes are enriched in risk factors identified for human psychiatric disorders. Lastly, we identify potential epigenetic regulatory elements and associated post-transcriptional modifications following high developmental GC exposure. Thus, we present a translationally relevant zebrafish model for studying stress hypersensitivity and alteration of behavior induced by exposure to elevated GC levels during development. Our study provides comprehensive datasets delineating potential molecular targets underlying the impact of developmental high GC exposure on adult responses.Competing Interest StatementSR holds a patent, European patent number 2928288 and US patent number 10,080,355: A novel inducible model of stress. The remaining authors declare no known competing interests.