Early-life challenge enhances cortisol regulation in zebrafish larvae

Creators: Castillo-Ramírez, Luis A.¹; Herget, Ulrich^{1, 2}; Ryu, Soojin^{1, 3}; De Marco, Rodrigo J.^{1, 4}

1. Max Planck Institute for Medical Research
2. California Institute of Technology
3. University of Exeter
4. Liverpool John Moores University

Abstract

The hypothalamic-pituitary-adrenal (HPA) axis in mammals and the hypothalamic-pituitary-interrenal (HPI) axis in fish are open systems that adapt to the environment during development. Little is known about how this adaptation begins and regulates early stress responses. We used larval zebrafish to examine the impact of prolonged forced swimming at 5 days post-fertilization (dpf), termed early-life challenge (ELC), on cortisol responses, neuropeptide expression in the nucleus preopticus (NPO), and gene transcript levels. At 6 dpf, ELC-exposed larvae showed normal baseline cortisol but reduced reactivity to an initial stressor. Conversely, they showed increased reactivity to a second stressor within the 30-min refractory period, when cortisol responses are typically suppressed. ELC larvae had fewer corticotropin-releasing hormone (crh), arginine vasopressin (avp), and oxytocin (oxt)-positive cells in the NPO, with reduced crh and avp co-expression. Gene expression analysis revealed upregulation of genes related to cortisol metabolism (hsd11b2, cyp11c1), steroidogenesis (star), and stress modulation (crh, avp, oxt). These results suggest that early environmental challenge initiates adaptive plasticity in the HPI axis, tuning cortisol regulation to balance responsiveness and protection during repeated stress. Future studies should explore the broader physiological effects of prolonged forced swimming and its long-term impact on cortisol regulation and stress-related circuits.

Copyright and License

© 2024. Published by The Company of Biologists Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution and reproduction in any medium provided that the original work is properly attributed

Acknowledgement

We would like to thank L. Flores-García for assistance with the experiments, Karl J. Iremonger and Chrysanthi Fergani for providing useful comments on a previous draft, R. Singer and A. Schoell for expert fish care, and R. Rödel for technical support. Also, we thank the reviewers for their valuable comments, which enhanced the quality of this manuscript.

Funding

This work was supported by the Max Planck Society, and Liverpool John Moores University. Open Access funding provided by Liverpool John Moores University.

Contributions

Conceptualization: L.A.C.-R., S.R., R.J.D.M.; Methodology: L.A.C.-R., U.H., S.R., R.J.D.M.; Validation: L.A.C.-R., R.J.D.M.; Formal analysis: L.A.C.-R., U.H., R.J.D.M.; Investigation: L.A.C.-R., U.H., R.J.D.M.; Resources: S.R., R.J.D.M.; Data curation: L.A.C.-R., U.H., R.J.D.M.; Writing - original draft: L.A.C.-R., U.H., R.J.D.M.; Writing - review & editing: S.R., R.J.D.M.; Visualization: R.J.D.M.; Supervision: S.R., R.J.D.M.; Project administration: S.R., R.J.D.M.; Funding acquisition: S.R., R.J.D.M.

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