Ecotoxicity Risk of Low-Dose Methylmercury Exposure to Caenorhabditis elegans: Multigenerational Toxicity and Population Discrepancy.

Methylmercury (MeHg) is a common organic form of mercury in water, which has been linked to several forms of biological toxicity. However, studies on the ecotoxicity risk of long-term exposure to low-dose MeHg are insufficient for the assessment of environmental safety. In the present study, the effects of MeHg on multiple generations (P0-F3) and population of Caenorhabditis elegans were investigated under long-term, low-dose exposure. We investigated the multigenerational toxicity of MeHg by analyzing reproductive and developmental indicators. According to our results, exposure to 100 nM MeHg had little effect on the parental generation (P0) but caused serious reproductive toxicity in the offspring (F1-F3), and the effect of MeHg was aggravated with each passing generation. The genes related to apoptosis and DNA damage were upregulated in the F3 generation. Pearson correlation analysis showed that the changes in these genes were closely related to the apoptosis of gonadal cells. Furthermore, chronic exposure to MeHg (from 100 to 1000 nM group) caused a sharp decline in population size and triggered the "bag of worms" phenotype. Genes related to vulvar development were downregulated in the F3 generation after treatment with 100 nM MeHg. These data suggest that long-term low-dose MeHg exposure adversely affected C. elegans and its offspring and triggered multigenerational toxicity and population discrepancy.

Assessment of Genotoxic Effects by Constructing a 3D Cellular System with Highly Sensitive Mutagenic Human-Hamster Hybrid Cells.

Owing to complex microenvironmental conditions, it is challenging to reflect the actual biological responses of tissues or the body in a two-dimensional (2D) cellular system. In the present study, a low-attachment-cultivation technique was employed to establish a highly sensitive 3D human-hamster hybrid (AL) model to study the mutagenic effects of environmental pollutants. The results showed that the established 3D system has apparent organizational characteristics. The average diameter and average cell number of the 3D cells were approximately 240 µm and 1500, respectively. The expression of stemness and cell-junction genes (biomarkers for 3D cells) was higher than that in 2D cells. The present study analyzed the mutagenic effects of the environmental carcinogens arsenite and silver nanoparticles using the established 3D system to demonstrate its efficiency in mutagenic assessment. The results showed that the mutagenic effects of arsenite (10 µM) and silver nanoparticles (10 µg/mL) were 70 ± 3 and 99 ± 7 per 105 survivors, respectively. These values were much lower than those from 2D AL cells and comparable to those from the in vivo system. These results suggest that the developed 3D-cell-culture model based on the 2D AL cellular system more effectively reflects the actual gene-mutation frequency of mutagens in vivo.