naphthoquinones and linsidomine

The modulation of cell signaling by nitric oxide (NO) and superoxide (O(-)(2)) is associated with apoptotic cell death in inflammatory kidney diseases. Recently, we have shown that NO induces ceramide production in glomerular mesangial and endothelial cells and the ratio of NO and O(-)(2) determines whether cells live or die.. Glomerular endothelial and mesangial cells were labeled with [(14)C]serine, the precursor of all sphingolipids, then stimulated with reactive oxygen species- or reactive nitrogen species-generating substances and subjected to lipid extraction. Radioactive lipids were separated and analyzed by thin-layer chromatography. DNA fragmentation, as a characteristic feature of apoptosis, was measured by a nucleosome/DNA-ELISA, which quantitatively recorded the histone-associated DNA fragments.. Exposure of glomerular endothelial and mesangial cells to either NO donors or superoxide-generating substances led to a delayed and sustained ceramide formation that paralleled the induction of apoptosis in both cell types. Coincubation of endothelial cells with NO and superoxide, which led to the generation of peroxynitrite, caused a synergistic enhancement of ceramide generation and apoptosis when compared to either stimulus alone. By contrast, in glomerular mesangial cells costimulation with superoxide neutralized not only NO-induced apoptosis but also NO-induced ceramide formation, although O(-)(2) alone triggered ceramide formation in mesangial cells and caused cell death. Moreover, SIN-1, a substance that simultaneously releases NO and O(-)(2) and thereby generates peroxynitrite, also stimulated a delayed ceramide formation in endothelial cells but not in mesangial cells. Furthermore, exposure of endothelial cells to glucose oxidase, which generates hydrogen peroxide, or to exogenous hydrogen peroxide, also showed a dose-dependent increase in ceramide formation and apoptosis, although to a lesser extent than did superoxide.. These data suggest that ceramide represents an important mediator of reactive oxygen and nitrogen species-triggered cell responses, like apoptosis. There seem to be cell type-specific protective mechanisms that critically depend on a fine-tuned redox balance between reactive nitrogen and oxygen species to determine whether a cell undergoes apoptosis or survives when exposed to oxidative and/or nitrosative stress conditions.

Topics: Animals; Apoptosis; Cattle; Cells, Cultured; Ceramides; DNA Fragmentation; Dose-Response Relationship, Drug; Drug Synergism; Kidney Glomerulus; Molsidomine; Naphthoquinones; Nitric Oxide; Nitric Oxide Donors; Spermine; Superoxides

The mutagenicity of three nitric oxide (NO) donors, 3-morpholinosydnonimine (SIN-1), a compound generating the precursors of peroxynitrite NO and superoxide, diethylamine/NO (DEA/NO) and spermine/NO (SPER/NO), both releasing authentic NO was analyzed using Escherichia coli tester strains IC203, carrying a deletion of the oxyR gene, and its oxyR(+) parent IC188 (the alternative name of WP2 uvrA/pKM101). The OxyR protein is a redox-sensitive transcriptional activator of genes encoding antioxidant enzymes. Strains IC203 and IC188 contain error-prone DNA polymerases polV, encoded by the chromosomal umuDC genes, and polRI, encoded by mucAB genes carried by pKM101. SIN-1 was determined to be an oxidative mutagen giving a positive response only in IC203, whereas DEA/NO and SPER/NO induced similar positive responses in IC203 and IC188 and were considered as non-oxidative mutagens. The spectrum of ochre suppressors in Trp(+) revertants induced by SIN-1 in IC203 was characterized by a higher number of TA-->AT transversions and GC-->AT transitions, and a lower number of GC-->TA transversions, with respect to the untreated control. The mutagenicity of SIN-1 in IC203, probably induced by peroxynitrite through reactive derivatives, was enhanced in the presence of plumbagin (PLB), a superoxide generator. Superoxide generation by PLB, as well as formation of peroxynitrite in cells treated with SIN-1, evaluated by monitoring the oxidation, respectively, of dihydroethidium and dihydrorhodamine 123, were greater in IC203 than in IC188. Formation of peroxynitrite in IC203 treated with SIN-1 was stimulated by PLB. After treatment with DEA/NO and SPER/NO the number of revertants scored in IC188 was higher than in strains IC187, containing only polV, and IC204, deficient in both polV and polRI. For these compounds, induced suppressor revertants in IC187 and IC204 were almost exclusively GC-->AT transitions, whereas in IC188 significant levels of GC-->TA and TA-->AT transversions were also induced. Mutagenesis by both DEA/NO and SPER/NO was partially inhibited in the presence of PLB. The results show the usefulness of the new tester strain IC203 to differentiate NO-promoted mutagenic mechanisms that involve or do not involve oxygen radicals.

Topics: Diethylamines; DNA Damage; Escherichia coli; Genes, Bacterial; Genes, Suppressor; Models, Genetic; Molsidomine; Mutagenicity Tests; Mutagens; Naphthoquinones; Nitric Oxide Donors; Spermine; Superoxides