Single and Combined Effects of Microplastics and Cadmium on the Cadmium Accumulation and Biochemical and Immunity of Channa argus.

Microplastics can accumulate residual drugs and heavy metals in the environment and accumulate through the layers of the food chain, ultimately causing harm to human health. The pollution of microplastics in the freshwater environment is becoming more and more serious, which directly affects the safety of aquatic organisms. This experiment studied the effects of single and composite microplastics and Cd on the tissue damage, antioxidant, and immune response of juvenile Channa argus. Microplastics with different diameters of 80 nm, 0.5 µm (200 µg/L), and Cd (50 µg/L) were used for exposure, and four sampling points were set for 24 h, 48 h, 96 h, and clear 48 h. Under different treatments, a certain degree of gill tissue damage can be found in 96 h. Microplastics and Cd can cause oxidative stress and affect the antioxidant status, and the impact of 0.5-µm microplastics is stronger than that of 80-nm microplastics. There is an antagonistic effect between the two microplastics and Cd during compound exposure, but the activity of CAT shows a synergistic effect. Microplastics and Cd affect the expression of immune-related genes to varying degrees. When exposed together, the expression of HSP70 gene all showed mutual antagonism, while the expression of IL-1ß gene was different. The expression of the MT gene can infer the ability of microplastics to accumulate Cd, and microplastics with a small diameter of 80 nm have stronger enrichment capabilities.

Benzo[a]pyrene induces microbiome dysbiosis and inflammation in the intestinal tracts of western mosquitofish (Gambusia affinis) and zebrafish (Danio rerio).

Benzo[a]pyrene (BaP) is one of the most well studied carcinogenic polycyclic aromatic hydrocarbons (PAHs) that has been associated with a wide range of toxic effects in aquatic organisms. In the present study, the mosquitofish and zebrafish were exposed to BaP (100 µg/L) for 15 days. We analyzed the intestinal microbial community of mosquitofish and zebrafish using 16S rRNA gene amplicon sequencing and also performed transcriptional profiling of the inflammation pathway related genes in the intestinal tissues. Our results showed that BaP exposure induced similar changes to the composition of microbial community in mosquitofish and zebrafish. At the phylum level, the abundance of Proteobacteria decreased while the abundance of Firmicutes increased following BaP exposure. At the genus level, a common pathogenic genus staphylococcus significantly increased in the BaP treatment groups, compared to the control (DMSO, ~0.001% v/v). In addition, it was observed that BaP significantly increased the mRNA level of il1ß in both mosquitofish and zebrafish. The transcript levels of il6, il8, il10 and ifnphi1 were significantly increased in zebrafish, however not in mosquitofish, following Bap exposure. Our findings suggest that BaP could induce microbiota dysbiosis and inflammation in the intestine of mosquitofish and zebrafish.