The present study aimed to explore the molecular mechanisms underlying the increase of nicotinamide adenine dinucleotide phosphate:quinine oxidoreductase 1(NQO1)and y-glutamylcysteine synthetase(γ-GCS)in brain tissue...The present study aimed to explore the molecular mechanisms underlying the increase of nicotinamide adenine dinucleotide phosphate:quinine oxidoreductase 1(NQO1)and y-glutamylcysteine synthetase(γ-GCS)in brain tissues after intracerebral hemorrhage(ICH).The microglial cells obtained from newborn rats were cultured and then randomly divided into the normal control group(NC group),model control group(MC group),rosiglitazone(RSG)intervention group(RSG group),retinoic-acid intervention group(RSG+RA group),and sulfbraphane group(RSG+SF group).The expression levels of NQO1,γ-GCS,and nuclear factor E2-related factor 2(Nrf2)were measured by real-time polymerase chain reaction(RT-PCR)and Western blotting,respectively.The results showed that the levels of NQO1,γ-GCS and Nrf2 were significantly increased in the MC group and the RSG group as compared with those in the NC group(P<0.01).They were found to be markedly decreased in the RSG+RA group and increased in the RSG+SF group when compared with those in the MC group or the RSG group(P<0.01).The RSG+SF group displayed the highest levels of NQO1,γ-GCS,and Nrf2 among the five groups.In conclusion,a medium dose of RSG increased the anti-oxidative ability of thrombinactivated microglia by increasing the expression of NQO1 and γ-GCS.The molecular mechanisms underlying the increase of NQO1 and γ-GCS in thrombin-activated microglia may be associated with the activation of Nrf2.展开更多
Glutathione is a key player in cellular redox homeostasis and, therefore, in the response to H2O2, but the factors regulating oxidation-activated glutathione synthesis are still unclear. We investigated H2O2-induced g...Glutathione is a key player in cellular redox homeostasis and, therefore, in the response to H2O2, but the factors regulating oxidation-activated glutathione synthesis are still unclear. We investigated H2O2-induced glutathione synthesis in a conditional Arabidopsis catalase-deficient mutant (cat2). Plants were grown from seed at elevated CO2 for 5 weeks, then transferred to air in either short-day or long-day conditions. Compared to cat2 at elevated CO2 or wild-type plants in any condition, transfer of cat2 to air in both photoperiods caused measurable oxidation of the leaf glutathione pool within hours. Oxidation continued on subsequent days and was accompanied by accumulation of glutathione. This effect was stronger in cat2 transferred to air in short days, and was not linked to appreciable increases in the extractable activities of or transcripts encoding enzymes involved in the committed pathway of glutathione synthesis. In contrast, it was accompanied by increases in serine, O-acetylserine, and cysteine. These changes in metabolites were accompanied by induction of genes encoding adenosine phosphosulfate reductase (APR), particularly APR3, as well as a specific serine acetyltransferase gene (SAT2.1) encoding a chloroplastic SAT. Marked induction of these genes was only observed in cat2 transferred to air in short-day conditions, where cysteine and glutathione accumulation was most dramatic. Unlike other SAT genes, which showed negligible induction in cat2, the relative abundance of APR and SAT2.1 transcripts was closely correlated with marker transcripts for H2O2 signaling. Together, the data underline the importance of cysteine synthesis in oxidant-induced up-regulation of glutathione synthesis and suggest that the chloroplast makes an important contribution to cysteine production under these circumstances.展开更多
基金grants from the National Natural Science Foundation of China(No.81560222)the Guizhou Science and Technology Foundation(No.[2017]7187,and No.[2013]2043).
文摘The present study aimed to explore the molecular mechanisms underlying the increase of nicotinamide adenine dinucleotide phosphate:quinine oxidoreductase 1(NQO1)and y-glutamylcysteine synthetase(γ-GCS)in brain tissues after intracerebral hemorrhage(ICH).The microglial cells obtained from newborn rats were cultured and then randomly divided into the normal control group(NC group),model control group(MC group),rosiglitazone(RSG)intervention group(RSG group),retinoic-acid intervention group(RSG+RA group),and sulfbraphane group(RSG+SF group).The expression levels of NQO1,γ-GCS,and nuclear factor E2-related factor 2(Nrf2)were measured by real-time polymerase chain reaction(RT-PCR)and Western blotting,respectively.The results showed that the levels of NQO1,γ-GCS and Nrf2 were significantly increased in the MC group and the RSG group as compared with those in the NC group(P<0.01).They were found to be markedly decreased in the RSG+RA group and increased in the RSG+SF group when compared with those in the MC group or the RSG group(P<0.01).The RSG+SF group displayed the highest levels of NQO1,γ-GCS,and Nrf2 among the five groups.In conclusion,a medium dose of RSG increased the anti-oxidative ability of thrombinactivated microglia by increasing the expression of NQO1 and γ-GCS.The molecular mechanisms underlying the increase of NQO1 and γ-GCS in thrombin-activated microglia may be associated with the activation of Nrf2.
文摘Glutathione is a key player in cellular redox homeostasis and, therefore, in the response to H2O2, but the factors regulating oxidation-activated glutathione synthesis are still unclear. We investigated H2O2-induced glutathione synthesis in a conditional Arabidopsis catalase-deficient mutant (cat2). Plants were grown from seed at elevated CO2 for 5 weeks, then transferred to air in either short-day or long-day conditions. Compared to cat2 at elevated CO2 or wild-type plants in any condition, transfer of cat2 to air in both photoperiods caused measurable oxidation of the leaf glutathione pool within hours. Oxidation continued on subsequent days and was accompanied by accumulation of glutathione. This effect was stronger in cat2 transferred to air in short days, and was not linked to appreciable increases in the extractable activities of or transcripts encoding enzymes involved in the committed pathway of glutathione synthesis. In contrast, it was accompanied by increases in serine, O-acetylserine, and cysteine. These changes in metabolites were accompanied by induction of genes encoding adenosine phosphosulfate reductase (APR), particularly APR3, as well as a specific serine acetyltransferase gene (SAT2.1) encoding a chloroplastic SAT. Marked induction of these genes was only observed in cat2 transferred to air in short-day conditions, where cysteine and glutathione accumulation was most dramatic. Unlike other SAT genes, which showed negligible induction in cat2, the relative abundance of APR and SAT2.1 transcripts was closely correlated with marker transcripts for H2O2 signaling. Together, the data underline the importance of cysteine synthesis in oxidant-induced up-regulation of glutathione synthesis and suggest that the chloroplast makes an important contribution to cysteine production under these circumstances.
