Project description:Minimal peroxide exposure of neuronal cells induces multifaceted adaptive responses.

Project description:Flavonoids are polyphenolic compounds with potent anti-oxidant and free radical scavenging activities. Here, we examined the cytoprotective actions of Quercetin-3-glucoside (Q3G) against oxidative stress induced by hydrogen peroxide. Pre-treatment of the neuroblastoma cells, SH-SY5Y with Q3G for 18 h reduced cell death after a brief exposure to hydrogen peroxide. The cytoprotective effects of Q3G were associated with decreased free radical generation suggesting that this mechanism accounts for Q3G-mediated cytoprotection. To address the possibility that Q3G-mediated cytoprotection involved alterations in gene expression, cDNA microarray studies were performed. These studies identified elevated expression of 25 genes and decreased expression of 3 genes only in Q3G pre-treated cells under oxidative stress. The majority of genes up-regulated by Q3G in SH-SY5Y cells under oxidative stress encode enzymes involved in lipid biosynthesis. Quantitative Real time PCR (qRT-PCR) validated changes in gene expression that were identified by cDNA microarray analyses. The induction of multitude of genes involved in cholesterol signaling pathway by Q3G in cells under oxidative stress suggests an important role for elevated cholesterol synthesis in the cytoprotective actions of Q3G. This hypothesis was confirmed by the detection of elevated levels of cholesterol in cells pre-treated with Q3G and subjected to oxidative stress. Moreover, inhibition of cholesterol biosynthesis with mevastatin blocked the cytoprotective effects of Q3G against oxidative stress-induced cell death. Taken together, these studies suggest a novel mechanism for flavonoid-induced cytoprotection involving elevated cholesterol synthesis that may act to reduce lipid peroxidation and promote membrane repair after oxidative injury. Keywords: cytoprotection, oxidative stress

Project description:Flavonoids are polyphenolic compounds with potent anti-oxidant and free radical scavenging activities. Here, we examined the cytoprotective actions of Quercetin-3-glucoside (Q3G) against oxidative stress induced by hydrogen peroxide. Pre-treatment of the neuroblastoma cells, SH-SY5Y with Q3G for 18 h reduced cell death after a brief exposure to hydrogen peroxide. The cytoprotective effects of Q3G were associated with decreased free radical generation suggesting that this mechanism accounts for Q3G-mediated cytoprotection. To address the possibility that Q3G-mediated cytoprotection involved alterations in gene expression, cDNA microarray studies were performed. These studies identified elevated expression of 25 genes and decreased expression of 3 genes only in Q3G pre-treated cells under oxidative stress. The majority of genes up-regulated by Q3G in SH-SY5Y cells under oxidative stress encode enzymes involved in lipid biosynthesis. Quantitative Real time PCR (qRT-PCR) validated changes in gene expression that were identified by cDNA microarray analyses. The induction of multitude of genes involved in cholesterol signaling pathway by Q3G in cells under oxidative stress suggests an important role for elevated cholesterol synthesis in the cytoprotective actions of Q3G. This hypothesis was confirmed by the detection of elevated levels of cholesterol in cells pre-treated with Q3G and subjected to oxidative stress. Moreover, inhibition of cholesterol biosynthesis with mevastatin blocked the cytoprotective effects of Q3G against oxidative stress-induced cell death. Taken together, these studies suggest a novel mechanism for flavonoid-induced cytoprotection involving elevated cholesterol synthesis that may act to reduce lipid peroxidation and promote membrane repair after oxidative injury. Keywords: cytoprotection

Project description:The Y79 retinoblastoma cells were exposed to oxidative stress conditions with hydrogen peroxide exposure. The differential gene expression profile on this condition was evaluated by comparing with untreated control Y79 cells. The cellular responses based on the differential gene expression was studied.

Project description:Oxidative stress, resulting from an imbalance in the accumulation and removal of reactive oxygen species such as hydrogen peroxide (H2O2), is a challenge faced by all aerobic organisms. In plants, exposure to various abiotic and biotic stresses results in accumulation of H2O2 and oxidative stress. Increasing evidence indicates that H2O2 functions as a stress signal in plants, mediating adaptive responses to various stresses. To analyze cellular responses to H2O2, we have undertaken a large-scale analysis of the Arabidopsis transcriptome during oxidative stress. Using cDNA microarray technology, we identified 175 non-redundant expressed sequence tags that are regulated by H2O2. Of these, 113 are induced and 62 are repressed by H2O2. A substantial proportion of these expressed sequence tags have predicted functions in cell rescue and defense processes. RNA-blot analyses of selected genes were used to verify the microarray data and extend them to demonstrate that other stresses such as wilting, UV irradiation, and elicitor challenge also induce the expression of many of these genes, both independently of, and, in some cases, via H2O2

Project description:Oxidative stress, resulting from an imbalance in the accumulation and removal of reactive oxygen species such as hydrogen peroxide (H2O2), is a challenge faced by all aerobic organisms. In plants, exposure to various abiotic and biotic stresses results in accumulation of H2O2 and oxidative stress. Increasing evidence indicates that H2O2 functions as a stress signal in plants, mediating adaptive responses to various stresses. To analyze cellular responses to H2O2, we have undertaken a large-scale analysis of the Arabidopsis transcriptome during oxidative stress. Using cDNA microarray technology, we identified 175 non-redundant expressed sequence tags that are regulated by H2O2. Of these, 113 are induced and 62 are repressed by H2O2. A substantial proportion of these expressed sequence tags have predicted functions in cell rescue and defense processes. RNA-blot analyses of selected genes were used to verify the microarray data and extend them to demonstrate that other stresses such as wilting, UV irradiation, and elicitor challenge also induce the expression of many of these genes, both independently of, and, in some cases, via H2O2. replicate_design

Project description:Clostridium thermocellum is a promising CBP candidate organism capable of directly converting lignocellulosic biomass to ethanol. Low yields, productivities and growth inhibition prevent industrial deployment of this organism for commodity fuel production. Symptoms of potential redox imbalance such as incomplete substrate utilization, and fermentation products characteristic of overflow metabolism, have been observed during growth. This perceived redox imbalance may be in part responsible for the mentioned bioproductivity limitations. Toward better understanding the redox metabolism of C. thermocellum, we analyzed gene expression, using microarrays, during addition of two stress chemicals (methyl viologen and hydrogen peroxide) which we observed to change fermentation redox potential. High quality RNA was extracted from C. thermocellum grown on cellobiose in chemostat culture and exposed, separately, to methyl viologen and hydrogen peroxide. Transcriptome profiles were obtained at seven time points during actively growing fermentations, 3 minutes, 15 minutes, 35 minutes, 7 hours, 14 hours, 50 hours, and 60 hours after beginning exposure to each stressor. Exposure treatments were carried out in duplicate and reference/untreated samples were taken before and between treatments, after flushing of stressor chemicals and re-equilibration of growth conditions.

Project description:Background: Pseudomonas aeruginosa, a pathogen infecting those with cystic fibrosis, encounters toxicity from phagocyte-derived reactive oxidants including hydrogen peroxide during active infection. P. aeruginosa responds with adaptive and protective strategies against these toxic species to effectively infect humans. Despite advances in our understanding of the responses to oxidative stress in many specific cases, the connectivity between targeted protective genes and the rest of cell metabolism remains obscure. Results: Herein, we performed a genome-wide transcriptome analysis of the cellular responses to hydrogen peroxide in order to determine a more complete picture of how oxidative stress-induced genes are related and regulated. Our data reinforce the previous conclusion that DNA repair proteins and catalases may be among the most vital antioxidant defense systems of P. aeruginosa. Our results also suggest that sublethal oxidative damage reduces active and/or facilitated transport and that intracellular iron might be a key factor for a relationship between oxidative stress and iron regulation. Perhaps most intriguingly, we revealed that the transcription of all F-, R-, and S-type pyocins was upregulated by oxidative stress and at the same time, a cell immunity protein (pyocin S2 immunity protein) was downregulated, possibly leading to self-killing activity. Conclusions: This finding proposes that pyocin production might be another novel defensive scheme against oxidative attack by host cells. Experiment Overall Design: We conducted four and five independent microarray experiments with biological replicates in the absence (control) and the presence (experimental) of hydrogen peroxide, respectively.

Project description:The Y79 retinoblastoma cells were exposed to oxidative stress conditions with hydrogen peroxide exposure. The differential gene expression profile on this condition was evaluated by comparing with untreated control Y79 cells. The cellular responses based on the differential gene expression was studied. One-color experiment,Organism: Human , Custom Whole Genome Human 8x60k designed by Genotypic Technology Pvt. Ltd. (Agilent-27114), Labeling kit: Agilent Quick-Amp labeling Kit (p/n5190-0442)

Project description:<p>Approximately 550,000 babies born prematurely each year in the United States suffer from birth at a time in development when the respiratory tract and immune system would normally be protected and maintained in a na&#239;ve state. This project is a component of the NIH Prematurity and Respiratory Outcomes Program (PROP) whose goals are the identification of disease mechanisms and biomarkers to stratify premature infants, at the time of discharge, for their risk of subsequent pulmonary morbidity. This Clinical Research Center (CRC) project will investigate prematurity-dependent alterations in cellular innate and adaptive immune systems resulting in increased susceptibility to respiratory infections and environmental irritants, and leading to respiratory morbidity in the first year of life. Prior studies have established developmental (maturity) and disease-related changes in circulating and pulmonary lymphocyte populations, but a comprehensive assessment of their relationship to disease risk/outcome has not been undertaken. We hypothesize that cellular and molecular immuno-maturity is altered due to intrinsic and extrinsic factors presented by premature birth in such a way as to reduce resistance to viral infections and to promote cytotoxic damage to the lung. We will evaluate immunologic maturity by comprehensively phenotyping lymphocyte populations in peripheral blood sampled at premature delivery, at the time of discharge from the hospital and at twelve months corrected age. The lymphocytic phenotype will be analyzed particularly in the context of gestational age and maternal-fetal stressors capable of modulating oxidative stress (oxygen exposure, infection and environmental tobacco smoke exposure). Additionally, we will assess changes in the molecular phenotype of isolated CD8 lymphocytes, a cell type preferentially recruited to the lungs of premature infants and capable of contributing to disease pathogenesis, by genome-wide expression profiling, in order to uncover novel disease pathways and define a gene expression signature associated with disease risk. We propose to build a statistical model, using cellular and molecular phenotypes and additional clinical variables, for stratifying risk of lung morbidity within the first year of life. Finally, we will assess the development of the gut microbiome in the preterm subjects to correlate with the observation of development of the adaptive immune system.</p>