Abstract
Engineered nanoparticles (ENPs) accumulate in marine sediments and exhibit adverse effects on benthic organisms. However, the effect of ENPs on marine benthic food chains is largely unknown. Herein, we investigated the trophic transfer and transformation of CeO(2) ENPs within a simulated marine benthic food chain from clamworm (Perinereis aibuhitensis) to turbot (Scophthalmus maximus), as well as their effects on fish flesh quality. The results showed that Ce contents in turbot increased with the accumulation of CeO(2) ENPs in clamworm, but no biomagnification of CeO(2) ENPs occurred along this food chain. During trophic transfer, CeO(2) ENPs in turbot experienced transformation from Ce(IV) to Ce(III). Importantly, CeO(2) ENPs accumulated in the muscle of turbot and decreased the crude protein, total amino acid, and delicious amino acid contents, as well as the texture of the muscle. CeO(2) ENPs induced the deterioration of flesh quality, which was mainly related to metabolism in muscle and intestinal disorders caused by oxidative stress. Specifically, CeO(2) ENPs increased the relative abundance of Stenotrophomonas and Vibrio in the turbot intestine, while decreasing those of Lactobacillus, Bacillus, and Acinetobacter. Significant disturbances in purine and amino acid (aspartate, glutamate, glycine, etc.) metabolism in muscle were induced by CeO(2) ENPs. Moreover, correlation analysis showed that microbiota dysbiosis was highly correlated with muscle metabolic dysfunction. Our study provides insights into the transfer and transformation of CeO(2) ENPs and their interference with fish flesh quality via the gut-muscle axis, providing useful information on assessing ecological risk and food safety in marine environments.