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Depuration and post-exposure recovery of oxidative stress responses to microplastics and cadmium in Pacific oyster (Crassostrea gigas)
Summary
Researchers exposed Pacific oysters to microplastic beads and cadmium, then transferred them to clean water to study recovery. They found that cadmium was eliminated much more slowly than the plastic beads, and oysters exposed to both contaminants together maintained higher levels of oxidative stress even during the recovery period. The study suggests that microplastics can enhance the toxic effects of heavy metals like cadmium through synergistic interactions that persist after the initial exposure ends.
Microplastics and trace metals such as cadmium (Cd) are environmental contaminants commonly co-occurring in marine ecosystems. We aimed to evaluate the impact of combined exposure of Pacific oyster (Crassostrea gigas) to microbeads (MBs) and Cd, focusing on the effects of the depuration process on contaminant removal and stress-related biomarkers. Pacific oysters were exposed to MBs, Cd, and their combination for 48 h, followed by a 72 h depuration process using uncontaminated seawater. We measured the levels of accumulated MBs and Cd in the whole soft tissue of the Pacific oysters to evaluate the degree of contaminant removal. Additionally, the concentrations of hydrogen peroxide were measured and the mRNA expression levels of antioxidant enzymes, metallothionein, and the apoptosis-related gene caspase-3 were analyzed in the Pacific oyster hepatopancreas tissue to evaluate oxidative stress and apoptosis. Our results indicated that Cd was eliminated more slowly than MBs, and the Pacific oysters exposed to combined MB and Cd contaminants maintained higher levels of oxidative stress-related gene expression than those exposed to individual contaminants. These findings suggest that Cd may persist longer in oyster tissues than MBs, potentially leading to prolonged toxicity in the Pacific oyster. Furthermore, in environments where both MBs and Cd are present, MBs can enhance the toxic effects of Cd through a synergistic interaction. Overall, we provide a reference for understanding the depuration and physiological responses of marine bivalves exposed to MBs and Cd.
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