Abstract
Arsenic trioxide (ATO), an industrial and environmental chemical with potential for accidental or intentional exposure, exerts profound neurotoxic effects. Its single acute exposure has been linked to delayed neurological and neurodegenerative outcomes. However, the molecular and cellular pathways driving these long-term manifestations remain poorly defined. In this study, combining human iPSC-derived neuronal and in vivo mouse model, we uncovered that the acute ATO exposure activates cellular stress pathway, which drives long-term neurotoxic and associated functional outcomes. We found that ATO induces integrated stress response (ISR) signaling in human iPSC-derived neurons. To model the impact of accidental ATO exposure in vivo , we administered a single high dose of ATO to C57BL/6J wild type mice. Four weeks post-treatment, ATO-exposed mice displayed neuropsychological symptoms and cognitive deficits. Brain analyses of ATO-challenged mice revealed elevated ISR activity marked by the increased phosphorylation of PERK and eIF2α and upregulation of the transcription factors, CHOP and ATF4. Transcriptomic profiling using bulk RNAseq revealed activation of pathways associated with stress and neuroinflammatory responses. Consistently, increased DNA damage and dysregulation of the STING-mediated innate immune response were also found in the brain of ATO-challenged mice. Pharmacological inhibition of the ISR with a small-molecule inhibitor, ISRIB mitigated ISR activation and preserved synaptic integrity in mouse hippocampal cells. In conclusion, our data identify ISR activation and DNA damage-driven immune dysregulation as key pathogenic drivers of ATO-induced delayed neurotoxicity and cognitive deficits and highlight ISR inhibitors as promising therapeutics to mitigate these effects.