Arsenic induces apoptosis in both cancerous and non-cancerous cells. The mechanism of arsenic-induced apoptosis is complex. We previously demonstrated that the antioxidant acetyl L-carnitine prevented sodium arsenite-induced apoptosis in zebrafish embryos. To gain more insight into the mechanism of arsenic-induced apoptosis, we explored the effect of another antioxidant, N-acetylcysteine (NAC). Co-treatment of sodium arsenite with 1 or 2 mM NAC had no effect on zebrafish development. There was a significant but partial reduction in apoptosis in the embryos co-treated with sodium arsenite and 1 mM NAC, while embryos treated with 1 mM NAC alone showed the loss of normal apoptosis that was observed in the control embryos. Complete abolition of apoptosis occurred in embryos co-treated with sodium arsenite and 2 mM NAC; however, 2 mM NAC alone resulted in 100% mortality, indicating antioxidant toxicity at high doses. NAC (1 mM) did not prevent sodium arsenite-induced increase in motor neurons, suggesting that arsenic-induced apoptosis and supernumerary motor neuron development are mediated via distinct pathways. To determine whether NAC prevented arsenic-induced apoptosis via reactive oxygen species (ROS) signaling, we assessed ROS levels and oxidative modification of proteins (carbonylation) using an OxyBlot assay. Neither sodium arsenite nor NAC altered protein oxidation, ROS levels, or p53, a pro-apoptotic protein, transcript levels. Additionally, dicoumarol, an inducer of p53 protein degradation, did not inhibit sodium arsenite-induced apoptosis. These results indicate that protein oxidation and p53 signaling are not involved in arsenic-induced apoptosis and that NAC prevents arsenic toxicity in zebrafish embryos through a hitherto unknown mechanism.
Keywords: apoptosis; arsenic; motor neurons; protein carbonylation; reactive oxygen species; zebrafish.