Transcription Factor Nrf2 Coordinately Regulates a Group of Oxidative Stress-inducible Genes in Macrophages
Electrophiles and reactive oxygen species have been implicated in the pathogenesis of many diseases. Transcription factor Nrf2 was recently identified as a general regulator of one defense mechanism against such havoc. Nrf2 regulates the inducible expression of a group of detoxication enzymes, such as glutathione Stransferase and NAD(P)H:quinone oxidoreductase, via antioxidant response elements. Using peritoneal macrophages from Nrf2-deficient mice, we show here that Nrf2 also controls the expression of a group of electrophileand oxidative stress-inducible proteins and activities, which includes heme oxygenase-1, A170, peroxiredoxin MSP23, and cystine membrane transport (system x c Ϫ ) activity. The response to electrophilic and reactive oxygen species-producing agents was profoundly impaired in Nrf2-deficient cells. The lack of induction of system x c Ϫ activity resulted in the minimum level of intracellular glutathione, and Nrf2-deficient cells were more sensitive to toxic electrophiles. Several stress agents induced the DNA binding activity of Nrf2 in the nucleus without increasing its mRNA level. Thus Nrf2 regulates a wideranging metabolic response to oxidative stress.
Transport system x c؊ found in plasma membrane of cultured mammalian cells is an exchange agency for anionic amino acids with high specificity for anionic form of cystine and glutamate. We have isolated cDNA encoding the transporter for system x c Ϫ from mouse activated macrophages by expression in Xenopus oocytes. The expression of system x c Ϫ activity in oocytes required two cDNA transcripts, and the sequence analysis revealed that one is identical with the heavy chain of 4F2 cell surface antigen (4F2hc) and the other is a novel protein of 502 amino acids with 12 putative transmembrane domains. The latter protein, named xCT, showed a significant homology with those recently reported to mediate cationic or zwitterionic amino acid transport when co-expressed with 4F2hc. Thus xCT is a new member of a family of amino acid transporters that form heteromultimeric complex with 4F2hc, with a striking difference in substrate specificity. The expression of system x c Ϫ was highly regulated, and Northern blot analysis demonstrated that the expression of both 4F2hc and xCT was enhanced in macrophages stimulated by lipopolysaccharide or an electrophilic agent. However, the expression of xCT was more directly correlated with the system x c Ϫ activity.
Cystine/glutamate transporter, designated as system x c ؊ , mediates cystine entry in exchange for intracellular glutamate in mammalian cells. This transporter consists of two protein components, xCT and 4F2 heavy chain, and the former is predicted to mediate the transport activity. This transporter plays a pivotal role for maintaining the intracellular GSH levels and extracellular cystine/cysteine redox balance in cultured cells. To clarify the physiological roles of this transporter in vivo, we generated and characterized mice lacking xCT. The xCT ؊/؊ mice were healthy in appearance and fertile.However, cystine concentration in plasma was significantly higher in these mice, compared with that in the littermate xCT ؉/؉ mice, while there was no significant difference in plasma cysteine concentration. Plasma GSH level in xCT ؊/؊ mice was lower than that in the xCT ؉/؉ mice. The embryonic fibroblasts derived from xCT ؊/؊ mice failed to survive in routine culture medium, and 2-mercaptoethanol was required for survival and growth. When 2-mercaptoethanol was removed from the culture medium, cysteine and GSH in these cells dramatically decreased, and cells started to die within 24 h. N-Acetyl cysteine also rescued xCT ؊/؊ -derived cells and permittedgrowth. These results demonstrate that system x c ؊ contributes to maintaining the plasma redox balance in vivo but is dispensable in mammalian development, although it is vitally important to cells in vitro.Transport of amino acids across plasma membrane is mediated by several transport systems in mammalian cells (1). We have described a Na ϩ -independent, cystine/glutamate exchange transport system, designated as system x c Ϫ , in various cultured cells like human fibroblasts and mouse peritoneal macrophages (2, 3). Cells expressing system x c Ϫ take up cystine in the medium into the cell, and reduce it to cysteine (thiol form), which is in turn used for the synthesis of GSH and proteins. A part of cysteine is released back into the medium via neutral amino acid transport systems, and the cysteine is rapidly oxidized to cystine by oxygen in the medium. Thus, a series of these transports and redox reactions constitutes cystine/cysteine cycle across the plasma membrane. The activity of system x c Ϫ contributes to driving the cystine/ cysteine cycle and to maintaining the redox balance between cystine and cysteine in the culture medium (4). In cultured cells, the activity of system x c Ϫ is also demonstrated to be essential for maintaining the intracellular GSH levels (5). Because GSH plays a central role in alleviating oxidative stress, system x c Ϫ is regarded as a constituent of the antioxidant defense systems, at least in cultured cells. This transporter is composed of two protein components, xCT and the heavy chain of 4F2 antigen (6), and the transport activity is thought to be mediated by xCT. The activity of system x c Ϫ is induced by various stimuli, including electrophilic agents like diethyl maleate (7), oxygen (4), hydrogen peroxide (8), bacterial lipopolysacchar...
Electrophile Response Element-mediated Induction of the Cystine/Glutamate Exchange Transporter Gene Expression
In mammalian cultured cells, the cystine/glutamate exchange transport mediated by system x c ؊ is important to maintain intracellular GSH levels. System x c ؊ consists of two protein components, xCT and the heavy chain of 4F2 antigen. The activity of system x c ؊ is induced by various stimuli, including electrophilic agents like diethyl maleate. In the present study, we have investigated the mechanism of the transcriptional regulation of xCT mRNA by diethyl maleate. The xCT gene consisted of twelve exons and sequence analysis identified four electrophile response element (EpRE)-like sequences between ؊230 and ؊1 in the 5-flanking region, designated EpRE-1 to EpRE-4. To identify sequences mediating the constitutive and induced expression of xCT, a series of 5-deletion mutants created from the 5-flanking region were cloned into a luciferase reproter vector and transfected into BHK21 cells. The 5-deletion analysis revealed that the sequence between ؊116 and ؊82 is essential for the basal expression and the sequence between ؊226 and ؊116 containing EpRE-1 is essential in response to diethyl maleate. Mutational analysis demonstrated that EpRE-1 is critically involved in the response to diethyl maleate. Other stress agents like arsenite, cadmium, and hydroquinone seemed to induce system x c ؊ activity via the same sequence. Furthermore, the experiments using the mouse embryonic fibroblasts derived from the Nrf2-deficient mice revealed that the induction of xCT gene by electrophilic agents is mediated by Nrf2. EpRE occurs in a broad spectrum of genes for the proteins that are involved in the defense against xenobiotics and regulates their expression. The present results have demonstrated that xCT is a novel member of this protein family.
Glutathione levels in neurons and glial cells were investigated in a neuronal-glial coculture and in separate cultures. Brain cell suspensions obtained from cerebral hemispheres of fetal rats were cultured, and after 5 days the glutathione content of this cell population, consisting mainly of neurons and astroglial cells, was 23.0 nmol/mg of cell protein, with a significantly high content in glial cells (28.0 nmol/mg of protein) in comparison with neurons (18.8 nmol/mg of protein). When the neurons and glial cells were separated and recultured in fresh medium, neuronal glutathione rapidly decreased, whereas glial glutathione remained unchanged. Cysteine is a rate-limiting precursor for glutathione synthesis, and its level was also decreased in neurons, but not in glial cells. Cysteine was taken up rapidly by both neurons and glial cells, but cystine was taken up only by glial cells. This accounts for the rapid decrease of glutathione in the cultured neurons, because the culture medium contains cystine, but not cysteine. It was also found that the cultured glial cells released cysteine into the medium. These results suggest that neurons maintain their glutathione level by taking up cysteine provided by glial cells.
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