Mice with a homozygous null mutation for the most abundant glutathione peroxidase, Gpx1, show increased susceptibility to the oxidative stress-inducing agents paraquat and hydrogen peroxide.

Glutathione peroxidases have been thought to function in cellular antioxidant defense. However, some recent studies on Gpx1 knockout (-/-) mice have failed to show a role for Gpx1 under conditions of oxidative stress such as hyperbaric oxygen and the exposure of eye lenses to high levels of H2O2. These findings have, unexpectedly, raised the issue of the role of Gpx1, especially under conditions of oxidative stress. Here we demonstrate a role for Gpx1 in protection against oxidative stress by showing that Gpx1 (-/-) mice are highly sensitive to the oxidant paraquat. Lethality was already detected within 24 h in mice exposed to paraquat at 10 mg.kg-1 (approximately (1)/(7) the LD50 of wild-type controls). The effects of paraquat were dose-related. In the 30 mg.kg-1-treated group, 100% of mice died within 5 h, whereas the controls showed no evidence of toxicity. We further demonstrate that paraquat transcriptionally up-regulates Gpx1 in normal cells, reinforcing a role for Gpx1 in protection against paraquat toxicity. Finally, we show that cortical neurons from Gpx1 (-/-) mice are more susceptible to H2O2; 30% of neurons from Gpx1 (-/-) mice were killed when exposed to 65 microM H2O2, whereas the wild-type controls were unaffected. These data establish a function for Gpx1 in protection against some oxidative stressors and in protection of neurons against H2O2. Further, they emphasize the need to elucidate the role of Gpx1 in protection against different oxidative stressors and in different disease states and suggest that Gpx1 (-/-) mice may be valuable for studying the role of H2O2 in neurodegenerative disorders.

Response of a primary human fibroblast cell line to H2O2: senescence-like growth arrest or apoptosis?

Hydrogen peroxide has been shown to induce either apoptosis or features of senescence in different cultured cell lines. We now show that both processes can be induced in the same culture of primary human diploid fibroblasts and that the outcome of apoptosis or the senescence-like phenotype is determined by the H2O2 concentrations. At 50 and 100 microM, H2O2 predominantly induced the senescence-like state, characterized by a reduced rate of proliferation, an increased number of cells in G0-G1, typically enlarged and flattened morphology, and increased CIP1 and fibronectin expression. At 300 and 400 microM, H2O2 mainly triggered apoptosis. At the intermediate 200 microM H2O2, features of both senescence and apoptosis were observed in the same culture. Thus, the higher the H2O2 concentration, the higher the proportion of cells undergoing apoptosis, suggesting a key role of the level of damage in the choice of a cell population to enter apoptosis and/or the senescence-like state. Before the induction of one or the other process, cells entered a transient "shock state" characterized by a typical morphological change, cell cycle arrest in G0-G1, and the induction of CIP1 and BCL-2.

Elevation in the ratio of Cu/Zn-superoxide dismutase to glutathione peroxidase activity induces features of cellular senescence and this effect is mediated by hydrogen peroxide.

Although reactive oxygen species have been proposed to play a major role in the aging process, the exact molecular mechanisms remain elusive. In this study we investigate the effects of a perturbation in the ratio of Cu/Zn-superoxide dismutase activity (Sod1 dismutases .O2-to H2O2) to glutathione peroxidase activity (Gpx1 catalyses H2O2 conversion to H2O) on cell growth and development. Our data demonstrate that Sod1 transfected cell lines that have an elevation in the ratio of Sod1 activity to Gpx1 activity produce higher levels of H2O2 and exhibit well characterised markers of cellular senescence viz. slower proliferation and altered morphology. On the contrary, Sod1 transfected cell lines that have an unaltered ratio in the activity of these two enzymes, have unaltered levels of H2O2 and fail to show characteristics of senescence. Furthermore, fibroblasts established from individuals with Down syndrome have an increase in the ratio of Sod1 to Gpx1 activity compared with corresponding controls and senesce earlier. Interestingly, cells treated with H2O2 also show features of senescence and/or senesce earlier. We also show that Cip1 mRNA levels are elevated in Down syndrome cells, Sod1 transfectants with an altered Sod1 to Gpx1 activity ratio and those treated with H2O2, thus suggesting that the slow proliferation may be mediated by Cip1. Furthermore, our data demonstrate that Cip1 mRNA levels are induced by exposure of cells to H2O2. These data give valuable insight into possible molecular mechanisms that contribute tribute to cellular senescence and may be useful in the evolution of therapeutic strategies for aging.

Measurement of thermally produced volatile alkanes: an assay for plant hydroperoxy fatty acid evaluation.

A new method designed to monitor lipid peroxidation in plants has been set up with soybean hypocotyl/radicles. The hydroperoxy fatty acids present in situ are converted by rapid thermal treatment (80 s and 210 J g-1) of the biological sample into ethane and n-pentane, which are analyzed by gas chromatography. The method has been directly calibrated by quantification of the hydroperoxy fatty acids by silica-phase HPLC analysis of their reduced hydroxy derivatives. Hypocotyl/radicles from the two soybean cultivars Argenta and Soriano were submitted to various chemical oxidative treatments and were analyzed for both thermally produced volatile alkanes and hydroperoxy fatty acid levels. Our results showed that ethane and n-pentane production are in both cases closely correlated with linolenic as well as linoleic acid hydroperoxide levels (P < 0.001). Within a given plant material, thermal conversion of both hydroperoxides into alkanes occurred with yields which were not dependent on the oxidative treatment. These yields are however functions of the biological material since in Soriano and Argenta cultivars they were around 6 and 25%, respectively. Taking into account the last point, the alkane test cannot be used to directly quantify the absolute lipid hydroperoxide levels of plant tissues but it is convenient to monitor the peroxidative phenomenon as it occurs. The assay is easy and rapid to perform (analysis of 50 samples per day) since no sample preparation is needed, and the low detection limit (20 pmol of alkane g-1) permits the analysis of small samples.

Light Stress and Oxidative Cell Damage in Photoautotrophic Cell Suspension of Euphorbia characias L.

A photoautotrophic cell-suspension culture of Euphorbia characias L. grown at 70 [mu]mol photons m-2 s-1 was very sensitive to light stress: the gross photosynthesis measured by using a mass spectrometric 16O2/18O2 isotope technique showed a fast decrease at a rather low light intensity of 100 [mu]mol photons m-2 s-1, far below the photosynthetic saturation level. The contribution of activated oxygen species on photosystem II photoinhibition was examined for a given light intensity. A protective effect on gross photosynthesis was observed with 1% oxygen. When light stress was applied to a methyl viologen-adapted cell suspension, photoinhibition was reduced. When 50 [mu]mol L-1 methyl viologen was added, photoinhibition was slightly enhanced. These responses suggested an involvement of superoxide radicals in the photoinhibition process of E. characias photoautotrophic cells. The long-term (16 h) effects of photoinhibition were then studied. Aldehyde (malondialdehyde and 4-hydroxyalcenals) production resulting from lipid peroxidation was stimulated in long-term stressed cells. When 50 [mu]mol L-1 methyl viologen were added, increased aldehyde production was measured. Under 1% oxygen, the aldehyde production was comparable to that of nonstressed cells. The relationship among lipid peroxidation, light intensity, and net photosynthesis suggests that aldehyde production may result from cell death provoked by a prolonged energy deficit due to the inhibition of photosynthesis.

Growth and photosynthesis of photoautotrophic callus derived from protoplasts of Solanum tuberosum L.

We describe a photoautotrophic culture procedure of potato (cvs Kennebec, Haig, DTO-33) callus derived from mesophyll protoplasts. The protoplast culture was initiated at very low concentration of glucose (down to 0.25 g l(-1)). Callus was subcultured under CO2 enriched air and glucose suppressed by the successive dilutions with glucose free media. Regeneration was successfully obtained under photoautotrophic conditions. The characterization of oxygen exchange and of some enzymes and metabolites of carbon assimilation indicated that chlorophyllous callus, grown on carbohydrate free medium, developed the photosynthetic pathway typical of C3 plants. By comparing the fresh weight of callus cultivated in the light or in non-photosynthetic conditions (in darkness or in the light +3-(3,4-Dichlorophenyl)-1,1-dimethylurea) we concluded that growth depended to about 70 to 88 % on photosynthesis.