Treatment with quercetin mitigates polystyrene nanoparticle-induced reduction in neuron capacity by inhibiting dopaminergic neurodegeneration and facilitating dopamine metabolism in Caenorhabditis elegans.

ABSTRACT

In organisms, long-term nanopolystyrenes (PS-NPs) exposure can cause toxicity, including neurotoxicity. Quercetin, the flavonol with extensive distribution within plants, possesses diverse biological activities. Nevertheless, the possible effect of quercetin to suppress PS-NPs-induced neurotoxicity and its associated mechanism remains unknown. Thus, in the present work, Caenorhabditis elegans was utilized as the model animal to investigate quercetin's pharmacological effect on suppressing PS-NPs-induced neurotoxicity and the underlying mechanism. PS-NPs exposure at 1-100 µg/L remarkably reduced locomotion behavior, while only PS-NPs exposure at 100 µg/L significantly decrease sensory perception behavior. Meanwhile, the increase in the number of worms with dopaminergic neurodegeneration was detected in nematodes exposed to 100 µg/L PS-NPs and the decreased dopamine content was observed within nematodes exposed to 10-100 µg/L PS-NPs, demonstrating the function of dopaminergic neurodegeneration and disruption of dopamine metabolism in inducing PS-NPs toxicity on neuron capacity. After 100 µg/L PS-NPs exposure, the 25-100 µM quercetin treatment effectively increased the locomotion behavior and the sensory perception behavior. Developmentally, quercetin treatment (100 µM) remarkably enhanced fluorescence intensity while decreasing worm number with neurodegeneration within BZ555 transgenic strains exposed to 100 µg/L PS-NPs. Physiologically, quercetin treatment (100 µM) significantly enhanced dopamine content within nematodes exposed to 100 µg/L PS-NPs. Molecularly, quercetin treatment (100 µM) notably decreased the expressions of genes governing neurodegeneration (mec-4, deg-3, unc-68, itr-1, clp-1, and asp-3) while significantly increasing the expression of genes governing dopamine metabolism (cat-2, cat-1, dop-1, dop-2, dop-3). As revealed by molecular docking results, quercetin might bind to excitotoxic-like ion channels receptors (MEC-4 and DEG-3) and dopamine secreted protein (CAT-2). Consequently, findings in this work demonstrated that long-term PS-NPs exposure within the µg/L range (1-100 µg/L) was toxic to neuron capacity, which was associated with the enhancement in dopaminergic neurodegeneration and disruption of dopamine metabolism. Notably, PS-NPs-mediated neurotoxicity to nematodes is probably suppressed through subsequent quercetin treatment.