An unusual NAD(P)H-dependent O2-.-enerating redox system in hepatoma 22a nuclei

Reactive oxygen species derived from the mitochondrial respiratory chain are not responsible for the basal levels of oxidative base modifications observed in nuclear DNA of Mammalian cells

The mitochondrial electron transport chain (ETC) is the most important source of reactive oxygen species (ROS) in mammalian cells. To assess its relevance to the endogenous generation of oxidative DNA damage in the nucleus, we have compared the background (steady-state) levels of oxidative DNA base modifications sensitive to the repair glycosylase Fpg (mostly 7,8-dihydro-8-oxoguanine) in wild-type HeLa cells and HeLa rho0 cells. The latter are depleted of mitochondrial DNA and therefore are unable to produce ROS in the ETC. Although the levels of ROS measured by flow cytometry and redox-sensitive probes in rho0 cells were only 10-15% those of wild-type cells, steady-state levels of oxidative DNA base modifications were the same as in wild-type cells. Mitochondrial generation of ROS was then stimulated in HeLa wild-type cells using inhibitors interfering with the ETC. Although mitochondrial ROS production was raised up to 6-fold, none of the substances nor their combinations induced additional oxidative base modifications in the nuclear DNA. This was also true for glutathione-depleted cells. The results indicate that the contribution of mitochondria to the endogenously generated background levels of oxidative damage in the nuclear DNA is negligible.

Enhancement of adriamycin toxicity by iron chelates is not a free radical mechanism

The possible involvement of metal ions and free radicals in the cytotoxic mechanism of Adriamycin (ADR) was investigated, using a model system of Escherichia coli cells. It is shown that E. coli mediated the production of free radicals under anaerobic (ADR-semiquinone) and aerobic (superoxide) conditions. ADR-induced loss of colony-forming ability was enhanced by the addition of iron (Fe) chelates. These observations suggested that a Fenton-type free radical mechanism was responsible for ADR toxicity. However, the mortality rate was essentially unchanged by the exclusion of oxygen. It was also unaffected by the addition of H2O2, catalase, or chelating agents. Cu(II), Zn(II) or Mg(II) had no effect on ADR toxicity. ADR and iron chelates did not induce measurable amounts of DNA strand-breaks. These observations suggest a mechanism of ADR-induced cell killing that is enhanced by Fe chelates, but does not directly involve oxygen-derived free radicals.

NADPH- and NADH-dependent oxygen radical generation by rat liver nuclei in the presence of redox cycling agents and iron

Redox cycling agents such as paraquat and menadione increase the generation of reactive oxygen species in biological systems. The ability of NADPH and NADH to catalyze the generation of oxygen radicals from the metabolism of these redox cycling agents by rat liver nuclei was determined. The oxidation of hydroxyl radical scavenging agents by the nuclei was increased in the presence of menadione or paraquat, especially with NADPH as the reductant. Paraquat, even at high concentrations, was relatively ineffective with NADH. The highest rates of generation of .OH-like species occurred with ferric-EDTA as the iron catalyst. Certain ferric complexes such as ferric-ATP, ferric-citrate, or ferric ammonium sulfate, which were ineffective catalysts for .OH generation in the absence of paraquat or menadione, were reactive in the presence of the redox cycling agents. Oxidation of .OH scavengers was sensitive to catalase and competitive .OH-scavenging agents under all conditions. The redox cycling agents increased NADPH-dependent nuclear generation of H2O2; stimulation of H2O2 production may play a role in the increase in .OH generation by menadione and paraquat. Menadione inhibited nuclear lipid peroxidation, whereas paraquat and adriamycin were stimulatory. The nuclear lipid peroxidation with either NADPH or NADH plus the redox cycling agents was not sensitive to catalase or .OH scavengers. These results indicate that the interaction of rat liver nuclei with redox cycling agents and iron leads to the production of potent oxidants which initiate lipid peroxidation or oxidize .OH scavengers. Although NADPH is more effective, NADH can also participate in catalyzing the production of reactive oxygen intermediates from the interaction of quinone redox cycling agents with nuclei. The ability of redox cycling agents to interact with various ferric complexes to catalyze nuclear generation of potent oxidizing species with either NADPH or NADH as reductants may contribute to the oxidative stress, toxicity, and mutagenicity of these agents in biological systems.

A comparison of the free radical properties of several anthracycline anti-tumour drugs and some of their analogues

NADPH consumption and esr spectroscopy have been used to study the rate of formation and signal intensity of free radicals produced by various anthracycline anti-tumour drugs in rat liver microsomal extract. The drugs investigated were Adriamycin, 4'Deoxyadriamycin, Daunorubicin, 4 Demethoxydaunorubicin and Carminomycin. Pulse radiolysis was also used to determine the case of reduction of each of the analogues to its semiquinone radical and some kinetic properties of the radicals produced. It is believed that the occurrence of reactions other than dismutation could be responsible for the shortened lifetimes of the semiquinone radicals observed in biological systems.