Abstract
Development is a tightly regulated process that establishes body axes and orchestrates the spatial organization of tissues and organs. Although developmental programs contain inherent redundancies, they remain highly sensitive to environmental cues. Among environmental contaminants, per- and polyfluoroalkyl substances (PFAS), chemicals that resist degradation and bioaccumulate in the body, are of particular concern. These "forever chemicals" are widespread in our household products, including non-stick and waterproof materials, and drinking water remains a major source of exposure. PFAS accumulate in specific tissues and have been associated with developmental delays, childhood leukemia, and other adverse health outcomes, yet the cellular and molecular mechanisms by which they disrupt early development remain largely unknown. To address this, we employ zebrafish embryos as a New Approach Methodology (NAM) to investigate how perfluorooctanoic acid (PFOA), a prevalent environmental PFAS, alters early embryogenesis. Embryos were exposed to physiologically relevant low and high doses of PFOA and analyzed at 24 hours post-fertilization (hpf), a key stage of organogenesis. We also included a parental exposure group, in which adults were treated with PFOA and their offspring were collected to assess whether the effects of exposure were transmitted to the next generation. Developmental processes are inherently plastic, and we wanted to understand the extent to which PFOA impacts normal cellular processes as well as the redundancy in the system (different developmental signaling pathways) which ensures that an embryo develops properly. Towards this, we performed single-nucleus RNA sequencing at 24 hpf, and it revealed that neuronal and muscle tissue clusters are particularly sensitive to PFOA exposure. These molecular perturbations correspond with anxiety-like behavioral phenotypes we observed in the exposed larvae, linking early developmental disruptions to organism-level outcomes. Overall, our findings provide mechanistic insight into the way in which PFAS exposure alters development, disrupting gene expression patterns and chromatin organization in developing tissues, revealing how early molecular perturbations can give rise to long-term behavioral consequences.