01) After NAC incubation, the expression of MDR-1 was elevated a

01). After NAC incubation, the expression of MDR-1 was elevated again, and there were significant

difference between the group with 100 μM NAC treatment and that without NAC treatment (◆ P < 0.01). Figure 6 The changes of EPO expressions by RT-PCR check details measurement. Letter N means the cells under normoxic condition; Letter H means the cells under hypoxic condition: (A) The representative gel picture was taken from three separate RT-PCR experiments. (B) Compared with hypoxic control, the analysis of relative densities showed that there was statistical difference the experimental cells by 100 and 200 μM BSO pretreatment respectively (# p < 0.01). After NAC incubation, the expression of EPO was elevated again, and there were significant difference between the group with 100 μM NAC treatment and that without NAC treatment (▲ P < 0.01). Discussion Among intracellular antioxidative factors, GSH is the tripeptide thiol L-γ-glutamyl-L-cysteinyl-glycine, a ubiquitous endogenous antioxidant. It plays an important role in maintaining intracellular

redox equilibrium and in augmenting cellular defenses in oxidative stress [20, 21]. In above antioxidant response, GSH is converted into glutathione oxidized disulfide (GSSG), which is recycled back to 2GSH by GSSG reductase, then forming what is known as a redox cycle. Under normal condition, the majority of glutathione is in the reduced form. Shifting redox equilibrium is in favor of a reducing or oxidizing state; that is in modification

of the redox status in cells [22, 23]. The γ-glutamylcysteine sythetase (γ-GCS) is the key rate-limiting enzyme synthesizing intracellular GSH, so intracellular GSH contents can Apoptosis inhibitor be decreased by the inhibition of γ-GCS [24, 25]. In the present study, our results showed that BSO, an inhibitor of γ-GCS, down-regulated the expression of GSH under Rho hypoxia condition and the inhibitory effect was concentration-dependent. Conversely, intracellular GSH contents could be increased by adding NAC to medium. It is therefore apparent that the ratios of GSH and GSSG revealed the alterations of redox status in hypoxic cells by redox reagents pretreatment. Interestingly, we also noted that, as a precursor of GSH biosynthesis, NAC could not significantly decrease the suppression of GSH contents in the cells by 200 μm BSO pretreatment. One possibility was that, as high-concentration of BSO irreversibly suppresses the most parts of γ-GCS activities [24], the synthesis of GSH had been saturated without conspicuous increased by the addition of enzyme substrate. Our following research showed that the down-regulation of HIF-1α in hypoxic cells by different concentrations BSO pretreatment, on the contrary, NAC could partly decrease the inhibitory effect. Similar to our results, the HKI 272 previous studies also showed that NAC, under chemical and physiological hypoxia, increased the expression of HIF-1α by changing cytoplasmic micro-environment redox state [26–28].

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