The transcription factor NF-E2-related nuclear factor 2 (Nrf2) regulates expression of genes that protect cells from oxidative damage. Here, we characterized nitric oxide (
Toxicity induced by nitric oxide (NO(*)) has been extensively investigated in many in vitro and in vivo experimental models. Recently, our laboratories found that both concentration and cumulative total dose are critical determinants of cell death caused by NO(*). Here, we report results of studies designed to define total dose thresholds and threshold effects for several NO(*)-induced toxicity and cellular responses and to determine impacts of p53 on them. We exposed human lymphoblastoid TK6 cells harboring wild-type p53 and isogenic p53-null NH32 cells to NO(*) delivered by a membrane delivery system. Cells were exposed at a steady state concentration of 0.6 microM for varying lengths of time to deliver increasing cumulative doses (expressed in units of microM min), and several end points of cytotoxicity and mutagenesis were quantified. Threshold doses for NO(*)-induced cytotoxicity were 150 microM min in TK6 cells and 300 microM min in NH32 cells, respectively. Threshold doses for NO(*)-induced apoptosis were identical to those for cytotoxicity, but mitochondrial depolarization thresholds were lower than those for cytotoxicity and apoptosis in both cell types. To gain insight into underlying mechanisms, cells of both types were exposed to sublethal (33% of cytotoxicity threshold), cytotoxicity threshold, or toxic (twice the cytotoxicity threshold) doses of NO(*). In TK6 cells (p53), the sublethal threshold dose induced DNA double-strand breaks, but nucleobase deamination products (xanthine, hypoxanthine, and uracil) in DNA were increased only modestly (<50%) by toxic doses. Increased mutant fraction at the thymidine kinase gene (TK1) locus was observed only at the toxic dose of NO(*). Treatment of NH32 cells with NO(*) at the threshold or toxic dose elevated mutagenesis of the TK1 gene, but did not cause detectable levels of DNA double-strand breaks. At similar levels of cell viability, the frequency of DNA recombinational repair was higher in p53-null NH32 cells than in wild-type TK6 cells. NO(*) treatment induced p53-independent cell cycle arrest predominately at the S phase. Akt signaling pathway and antioxidant proteins were involved in the modulation of toxic responses of NO(*). These findings indicate that exposure to doses of NO(*) at or above the cytotoxicity threshold dose induces DNA double-strand breaks, mutagenesis, and protective cellular responses to NO(*) damage. Furthermore, recombinational repair of DNA may contribute to resistance to NO(*) toxicity and potentially increase the risk of mutagenesis. The p53 plays a central role in these responses in human lymphoblastoid cells.
SIN-1 (3-morpholinosydnonimine), the active metabolite of the vasodilator drug molsidomine, decomposes spontaneously in solution. In the presence of oxygen, NO* and O(2)(*-) are released, generating peroxynitrite, a potent oxidizing agent, at a constant rate over a 2 h period. We utilized this system to investigate mechanisms of peroxynitrite-induced cytotoxicity, genotoxicity, apoptosis, and mitochondrial damage in two human lymphoblastoid cell lines carrying either wild-type (TK6 cells) or mutant p53 (WTK-1 cells) genes. Treatment of TK6 cells with 5 mM SIN-1 for 1.5 h resulted in 28 +/- 6% survival 24 h later. Exposure in the presence of different radical scavengers significantly increased survival, as follows: cytochrome c, 96 +/- 3%; Tiron, 69 +/- 0%; SOD plus catalase, 83 +/- 5%; carboxy-PTIO, 87 +/- 3%; and uric acid, 87 +/- 2%. D-mannitol was ineffective in reducing lethality, as were SOD and catalase when added individually or in heat-inactivated form. Spontaneous as well as SIN-1-induced mutant fractions (MF) in both HPRT and TK genes were significantly higher in WTK-1 cells than in TK6 cells (p < 0.05-0.01). Exposure to 2.5 mM SIN-1 induced time-dependent apoptosis in TK6 cells, but not in WTK-1 cells. Mitochondrial membrane depolarization was also observed in both cell lines after SIN-1 treatment. Neutral comet assay demonstrated that SIN-1 treatment resulted in higher levels of DNA double-strand breaks in TK6 cells than in WTK-1 cells. Collectively, these data show that SIN-1 can be used as an effective peroxynitrite generator in cell culture experiments under these experimental conditions, in which it induced a greater apoptotic response but was less potent as a mutagen in TK6 cells compared with WTK-1 cells. Thus, p53 status was an important determinant of SIN-1 induced mutagenesis and apoptosis in these two human lymphoblastoid cell lines.
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