Mari Ohta

Oxidative stress-induced cellular damage caused by UV and methyl viologen in Euglena gracilis and its suppression with rutin.

The effects of ultraviolet radiation (UV-A: 320-400 nm and UV-B: 280-320 nm) and methyl viologen (MV) single or combined exposure, on the cell growth, viability and morphology of two strains of the unicellular flagellate Euglena gracilis, using the Z strain as a plant model and the achlorophyllous mutant SMZ strain as an animal model were investigated. Cell growth was not affected by MV only, whereas UV-A or UV-B single and combined exposure with MV inhibited the cell growth or decreased the viability. The SMZ strain had a higher number of abnormal cells than the Z strain after the third dose of UV-B was delivered simultaneously with MV. The abnormal cell number decreased when E. gracilis SMZ cells were preincubated with 100 microM rutin prior to the UV-B and MV exposure. There were higher abnormal cell numbers with groups exposed to UV rather than MV single exposure. Combined exposure to UV-B and 200 microM MV induced the highest levels of TBARS in both strains, and with the supplementation of rutin these high levels were suppressed. These results suggest that UV-A or UV-B irradiation alone or combined with MV cause considerable oxidative damage in E. gracilis cells, and rutin supplementation may suppress their adverse effects.

Effect of Several Solutions Including Mineral-encaging Zeolites on the Restoration of Cell Motility of Tributyltin-intoxicated Euglena gracilis Z.

To examine the detoxification effect of mineral-encaged zeolites on cells impaired by pollutant-intoxication, we used a bioassay system involving Euglena gracilis Z as the model organism and TBTCl as a pollutant. TBTCl exposure causes Euglena cells to quickly change shape from a spherical to spindle form, with the process being reversible by detoxification. Taking advantage of this morphological characteristic, we examined the restoration of motility by water containing zeolites encaging different minerals. TBTCl-intoxicated Euglena cells were incubated in processed water with different types of mineral-encaging zeolites for up to 3 hours. The restoration of motility was evaluated by observing the number of motile cells with a video microscope. Remarkable recovery was observed in the incubation systems with water containing Fe-, Zn-, and Mn-encaging zeolites. However, the effect was suppressed when the water species were treated with the chelator, Chelex-100(®). An equivalent concentration of FeCl3 to that in the Fe-encaging zeolite processed water did not show significant restoration effect.

Detoxification effect of iron-encaging zeolite-processed water in tributyltin-intoxicated Euglena gracilis Z.

In our previous paper, we reported the restoration promoting effects of mineral-encaging zeolite-processed water, especially of a Fe-encaging one, on tributyltin chloride (TBTCl)-intoxicated Euglena gracilis. This present study extends the investigation on the behavior of TBTCl and a xenobiotic enzyme, cytochrome P-450, in Euglena cells incubated with or without Fe-encaging zeolite-processed water (FeZW). Subcellular fractionation of TBTCl-intoxicated Euglena cells, atomic absorption spectrophotometry, and GC analyses showed that TBTCl was rapidly incorporated into the cells to halt cell motility. GC-MS showed that FeZW promoted conversion of TBTCl to dibutyltin (DBT) as the major metabolite in the microsomal fraction of the cells. An in vitro incubation system with heat-treated microsomes did not convert TBTCl to DBT. The contribution of cytochrome P-450 in the microsomal fraction was suggested by an immunochemical method. The results suggest that the improvement of detoxification by FeZW in the TBT-intoxicated Euglena cells should be due to activation of biotransformation system of the Euglena cells by FeZW.

Detoxifying Effect of Desalinated Deep Seawater on Organotin-poisoned Euglena gracilis

A Euglena gracilis Z strain was used as a biomarker to examine the detoxifying effects of desalinated deep seawater (DDSW) and surface seawater (DSSW) on the hazardous chemical, tributyltin chloride (TBTCl). A distinct restoration effect on cell motility was observed after incubating with DDSW. The effect was largely attributed to magnesium, calcium and silicon that are involved in cell motility and morphology.