2024 article

Developmental exposure to pesticides that disrupt retinoic acid signaling causes persistent retinoid and behavioral dysfunction in zebrafish

Hawkey, A. B., Shekey, N., Dean, C., Asrat, H., Koburov, R., Holloway, Z. R., … Levin, E. D. (2024, January 17). TOXICOLOGICAL SCIENCES.

By: A. Hawkey*, N. Shekey n, C. Dean*, H. Asrat*, R. Koburov*, Z. Holloway*, S. Kullman n, E. Levin*

author keywords: zebrafish; development; neurobehavioral toxicology; retinoic acid receptors
TL;DR: It is demonstrated that early developmental exposure to environmental toxicants that interfere with RA signaling cause short as well as long-term behavioral disruption in a well-established zebrafish behavioral model and the meaning of the RA adverse outcome pathway is expanded, indicating that observed effects likely correspond with the nature of underlying homeostatic effects. (via Semantic Scholar)
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Source: Web Of Science
Added: January 29, 2024

Abstract Early developmental exposure to environmental toxicants may play a role in the risk for developing autism. A variety of pesticides have direct effects on retinoic acid (RA) signaling and as RA signaling has important roles in neurodevelopment, such compounds may cause developmental neurotoxicity through an overlapping adverse outcome pathway. It is hypothesized that a pesticide’s embryonic effects on retinoid function may correspond with neurobehavioral disruption later in development. In the current studies, we determined the effects of RA-acting pesticides on neurobehavioral development in zebrafish. Buprofezin and imazalil caused generalized hypoactivity in the larval motility test, whereas chlorothalonil and endosulfan I led to selective hypoactivity and hyperactivity, respectively. With buprofezin, chlorothalonil, and imazalil, hypoactivity and/or novel anxiety-like behaviors persisted in adulthood and buprofezin additionally decreased social attraction responses in adulthood. Endosulfan I did not produce significant adult behavioral effects. Using qPCR analyses of adult brain tissue, we observed treatment-induced alterations in RA synthesis or catabolic genes, indicating persistent changes in RA homeostasis. These changes were compound-specific, with respect to expression directionality, and potential patterns of homeostatic disruption. Results suggest the likely persistence of disruptions in RA signaling well into adulthood and may represent compensatory mechanisms following early life stage exposures. This study demonstrates that early developmental exposure to environmental toxicants that interfere with RA signaling causes short as well as long-term behavioral disruption in a well-established zebrafish behavioral model and expand upon the meaning of the RA adverse outcome pathway, indicating that observed effects likely correspond with the nature of underlying homeostatic effects.