Toxic responses in rat embryonic cells to silver nanoparticles and released silver ions as analyzed via gene expression profiles and transmission electron microscopy.

After exposing rat embryonic cells to 20 mg/mL of silver nanoparticle (NP) suspension and their released ions for different time periods, silver nanoparticles were found in cellular nuclei, mitochondria, cytoplasm and lysosomes by transmission electron microscopy (TEM). We also observed Global gene expression analysis showed a total of 279 genes that were up-regulated and 389 genes that were down-regulated in the silver-NP suspension exposure group, while 3 genes were up-regulated and 41 genes were down-regulated in the silver ion exposure group. Further, the GO pathway analysis suggested that these differentially expressed genes are involved in several biological processes, such as energy metabolism, oxygen transport, enzyme activities, molecular binding, etc. It is possible that inhibition of oxygen transport is mediated by the significant down-regulation of genes of the globin family, which might play an important role in silver ion-induced toxicity. KEGG pathway analysis showed that there were 23 signal pathways that were affected in the cells after exposure to silver-NP suspension, but not silver ion alone. The most significant change concerned inflammatory signal pathways, which were only found in silver-NP suspension exposed cells, indicating that inflammatory response might play an important role in the mechanism(s) of silver-NP-induced toxicity. The significant up-regulation of matrix metalloproteinases 3 and 9 suggests that silver NPs could induce extracellular matrix degradation via an inflammatory signaling pathway. The significant up-regulation of secretory leukocyte peptidase inhibitor and serine protease inhibitor 2c was considered to be an embryonic cellular defense mechanism in response to silver-NP-induced inflammation.