YONPs induce selective cytotoxicity, genomic instability, oxidative stress and ROS mediated mitochondrial apoptosis in human epidermoid skin A-431 Cancer cells.

Yttrium oxide nanoparticles (YONPs) have emerged as a promising avenue for cancer therapy, primarily due to their distinctive properties that facilitate selective targeting of cancer cells. Despite their potential, the therapeutic effects of YONPs on human epidermoid skin cancer remain largely unexplored. This study was thus conducted to investigate the impact of YONPs on both human skin normal and cancer cells, with an emphasis on assessing their cytotoxicity, genotoxicity, and the mechanisms underlying these effects. Cell viability and apoptosis induction were assessed using the Sulforhodamine B and chromatin diffusion assay, respectively. Reactive oxygen species (ROS) level, mitochondrial membrane potential integrity, oxidative stress markers and expression level of apoptotic and mitochondrial genes were also estimated. Our findings highlight the selective and significant cytotoxicity of YONPs against human epidermoid A-431 cancer cells. Notably, exposure to five YONPs concentrations (0.1, 1, 10, 100 and 1000 µg/ml) resulted in a high concentration-dependent reduction in cell viability and a corresponding increase in cell death observed 72 h post-treatment specifically in A-431 cancer cells, while normal skin fibroblast (HSF) cells exhibited minimal toxicity. When A-431 cancer cells were treated with the half-maximal inhibitory concentration (IC50) of YONPs for 72 h, a significant increase in ROS generation was noted. This led to oxidative stress, along with severe damage to genomic DNA and mitochondrial membrane potential, triggering substantial apoptosis. Furthermore, a concurrent significant upregulation of apoptotic p53 and mitochondrial ND3 genes was observed, coupled with a notable decrease in the anti-apoptotic Bcl2 gene expression.Overall, YONPs demonstrate considerable promise as a therapeutic agent for skin epidermoid cancer due to their ability to selectively target and induce cytotoxic effects in A-431 cancer cells, all while causing minimal harm to normal HSF cells. This selective cytotoxicity appears to be associated with YONPs' ability to induce excessive ROS production and subsequent oxidative stress, leading to significant genomic DNA fragmentation, loss of mitochondrial permeability, and alterations in apoptotic and mitochondrial genes' expression, ultimately promoting apoptosis in A-431 cancer cells. These findings establish a foundation for further research into the utilization of YONPs in targeted cancer therapies and underscore the necessity for ongoing investigation into their safety and efficacy in clinical applications.