Phagocytic clearance of electric field induced 'apoptosis-mimetic' cells.

Cells undergoing apoptosis lose lipid asymmetry that is often manifested by the exposure of phosphatidylserine (PS) to the outer surface of the cell membrane. Macrophages and other cell types recognize externalized PS to signal phagocytosis, thereby eliciting a non-inflammatory response. PS exposure is obligatory in the recognition and clearance of apoptotic cells. Here, we find that externally applied moderate electric field induces PS externalization in a mouse B-cell (FOX-NY) membrane without procaspase-3 activation, a major characteristic of apoptotic cells. The field-induced PS inversion is caused as a result of electroporation and/or a process involving membrane reorganizations and recovery that ensues following field exposure. Using a mouse macrophage cell line (J7444A.1) from the same strain, we show phagocytic clearance of PS expressing B-cells and demonstrate that this is in part due to the apoptosis mimicry of the field exposed cells.

Mitochondria play no roles in Mn(II)-induced apoptosis in HeLa cells.

Manganese(II) has been shown to exhibit catalase-like activity under physiological conditions. In the course of studies to test the antioxidant activity of Mn(II) on HeLa cells, it was observed at high concentrations (1-2 mM) that Mn(II) also induced apoptosis, as judged by changes in cell morphology, caspase-3 activation, cleavage of poly(ADP) ribose, and DNA condensation. However, in contrast to established mechanisms, the Mn(II)-induced apoptosis is associated with an increase rather than a decrease in mitochondrial inner-membrane potential, as monitored by the fluorescent probe tetramethylrhodamine ethyl ester. Based on immunochemical analysis, Mn(II)-induced apoptosis does not lead to the release of cytochrome c into the cytosol. These and other measurements show that treatment with Mn(II) leads to enhancement of the mitochondrial "membrane mass," has no effect on mitochondrial volume, and does not affect the permeability transition pore. Together, these results support the view that Mn(II)-induced apoptosis occurs by a heretofore unrecognized mechanism. In addition, it was demonstrated that Mn(II) treatment leads to an increase in the production of reactive oxygen species (peroxides) and to the induction of the manganese superoxide dismutase and catalase activities but has no effect on the Cu,Zn-superoxide dismutase level.

DNA strand scission by the nephrotoxin [2,2'-bipyridine]-3,3',4,4'-tetrol-1,1'-dioxide and related compounds in the presence of iron.

The capacity of non-illuminated nephrotoxin orellanine ([2,2'-bipyridine]-3,3',4,4'-tetrol-1,1'-dioxide) to induce DNA damage in the presence of ferrous iron and dioxygen has been evaluated. Maximal single-strand breaks in plasmid DNA were obtained with a metal to ligand ratio 1:3. Instantaneous oxidation of Fe2+ in presence of orellanine under air was responsible for oxy-radical production concomitant to a stable ferric complex Fe(III)Or3 formation, leading to oxidative DNA breakage at physiological pH. DNA damage was lowered in the presence of SOD and catalase or DMSO, indicating a set of reactions that leads to oxy-radical generation. Iron chelators such as DTPA and EDTA had no protecting effect, Desferal slightly protected. GSH acted as an oxy-radical scavenger, whereas cysteine induced stronger damage. Closely related bipyridine compounds were also studied in presence of Fe2+ and O2 using a combination of spin-trapping and DNA-nicking experiments, none of which were able to chelate iron and induce damage at pH 7. Both catecholic moieties and aminoxide groups are required for observing breakage at physiological pH.

Protection by selenoprotein P in human plasma against peroxynitrite-mediated oxidation and nitration.

In order to study functions of selenoprotein P in human plasma, its level was lowered via two techniques, chromatography on Sepharose-bound heparin, or immunoprecipitation; Western blot analysis showed that both techniques were effective at substantially lowering selenoprotein P levels in plasma. When peroxynitrite was infused to maintain a 0.9 microM steady-state concentration, plasma made deficient in selenoprotein P diminished benzoate hydroxylation significantly less than control plasma. Similar differences were found for protein 3-nitrotyrosine formation, determined by Western blot analysis. Conversely, in a selenoprotein P-enriched plasma preparation obtained via heparin-Sepharose chromatography, protection against benzoate hydroxylation was above controls. Likewise, a supernatant from control plasma that had been exposed to anti-selenoprotein P antibodies was less efficient in preventing oxidation and nitration reactions of peroxynitrite than the supernatant from plasma exposed to a non-specific antibody (rabbit anti-sheep IgG). These data demonstrate a role of selenoprotein P in human plasma in the defense against peroxynitrite.

Peroxidase-mediated oxidation, a possible pathway for activation of the fungal nephrotoxin orellanine and related compounds. ESR and spin-trapping studies.

Orellanine is the tetrahydroxylated and di-N-oxidized bipyridine toxin extracted from several Cortinarius mushrooms among them C. orellanus. The pathogenic mechanism involved in the C. orellanus-poisoning by orellanine leading to kidney impairment is not yet fully understood until now. Electron spin resonance (ESR) spectroscopy has been used to study the activation of orellanine by horseradish peroxidase/H2O2 system at physiological pH. Evidence for a one-electron oxidation of the toxin by this enzymatic system to an ortho-semiquinone radical intermediate is presented. The orellanine ortho-semiquinone generated by the peroxidase/H2O2 system abstracts hydrogen from glutathione, generating the glutathionyl radical which is spin-trapped by 5,5'-dimethyl-1-pyrroline N-oxide (DMPO) and subsequently detected by ESR spectroscopy. Similarly, the ortho-semiquinone abstracts hydrogen from ascorbic acid to generate the ascorbyl radical which is detected by direct ESR. The peroxidatic oxidation of orellanine to semiquinone followed by its reduction by glutathione or ascorbic acid does not induce dioxygen uptake. The relationship between chemical structure and HRP oxidation of orellanine-related molecules, namely orelline and DHBPO2 (the parent molecule lacking of hydroxyl groups in 3 and 3' position) has been investigated in absence or in presence of reducing agents. None of the orellanine-related compounds can be oxidized by the HRP/H2O2 system, showing that both catecholic moieties and aminoxide groups are necessary for observing the formation of the ortho-semiquinone form of orellanine. As shown for the (photo)chemical oxidation of orellanine, the mechanism of toxicity could be correlated with a depletion of glutathione and ascorbate levels which are implicated in the defence against oxidative damage.

Novel methods for identification and quantification of the mushroom nephrotoxin orellanine. Thin-layer chromatography and electrophoresis screening of mushrooms with electron spin resonance determination of the toxin.

Orellanine, (2,2'-bipyridine)-3,3',4,4'-tetrol-1,1'-dioxide, the toxin from several Cortinariace species, induces an acute renal failure which can be very severe or even irreversible and fatal. It is therefore important to be able to quickly and simply identify orellanine in mushroom samples with classical methods, readily available in any laboratory, such as anti-poison centers. This article reports the results of three analytical methods: classical TLC on cellulose plates in n-butanol--acetic acid--water and two original methods, electrophoresis on agarose gel and direct electron spin resonance (ESR) after enzymatic oxidation. They were applied to detect orellanine in 34 Cortinariaceae and 4 other species of toadstools. Our three sets of results are convergent. TLC (detection limit: 15 ng with fluorescence densitometry), electrophoresis (25 ng) and even ESR (5 micrograms), are sensitive enough for our purpose, and a sophisticated method like HPLC (detection limit: 50 pg) is not required. As the ESR spectrum of the toxin semiquinone is highly specific, TLC or electrophoresis coupled with ESR are a convenient alternative to liquid chromatography coupled with mass spectrometry, with the same specificity, for a confirmation or with samples such as ours with high toxin contents. ESR unambiguously confirms the relatively high contents of orellanine, from 0.45% (C. henrici) to 1.1-1.4% (C. orellanus), found in five Cortinarius from the subgenus Leprocybe, section Orellani. The five species, though they are from different geographic origins, have a more or less common pattern of fluorescent compounds, among which orellinine and orelline beside orellanine. It can be useful to note that orellanine semiquinone can be easily detected by ESR directly in the fresh mushroom. The toxin is absent in the other mushrooms we tested, especially in D. cinnamomea and C. splendens, which have been claimed as toxic and suspected to contain orellanine.