Project description:In our current study, SisPerR was revealed as a transcriptional repressor in response to oxidative stress in Saccharolobus islandicus REY15A. Deletion of sisperR abolishes the oxidative stress-induced expression of a large number of genes. To identify the target genes directly bound by SisPerR in vivo, chromatin immunoprecipitation-sequencing (ChIP-seq) was performed.

Project description:Quorum sensing controls the expression of multiple virulence factors. PA14 genes lasR and rhlR are necessary for quorum sensing via homoserine lactones. A PA14 lasR rhlR deficient mutant exhibits a reduced oxidative stress response. Here we conducted a microarray to determine oxidative stress response gene regulation mediated by the homoserine lactone quorum sensing circuits. A PA14 lasR rhlR deficient mutant was compared to the wild-type with and without H2O2 stress.

Project description:Excessive levels of reactive oxygen species (ROS) cause cellular stress through damage to all classes of macromolecules and result in cell death. However, ROS can also act as signaling molecules in various biological processes. In plants, ROS signaling has been documented in environmental stress perception, plant development and cell death amongst others. Knowledge on the regulatory events governing ROS signal transduction is however still scratching the surface. To further elucidate the transcriptional response and regulation upon ROS accumulation we supplemented Arabidopsis seedlings with a 10mM hydrogen peroxide (H2O2) solution to trigger oxidative stress. After growth of 7 days, hydrogen peroxide (H2O2) was added to a final concentration of 10mM. Control plants were treated with the same volume of H2O. Seedlings were grown for 24h under the same controlled conditions. Design: 3 replicates x 2 conditions (7+1 day H2O or 7+1 day H2O2)

Project description:Iron (Fe) is an essential micronutrient whose uptake is tightly regulated to balance both deficiency and Fe excess induced oxidative stress. The non-essential heavy metal cadmium (Cd) both induces oxidative stress and an Fe deficiency like response. It is unclear how Cd induces this response, nor how it relates to Fe status sensing. Using next generation sequencing, H2O2 quantification in both wild type and the Fe over-accumulating mutant opt3-2, we explored how Cd interferes with Fe sensing. We found a large overlap of genes consistently responsive to Fe deficiency and Cd in both leaves and roots. Two subnetworks emerged dependent on the high Fe and H2O2 concentration in opt3-2, while opt3-2 chloroplasts showed reduced photosynthetic efficiency during Cd exposure, indicating that they are one source of H2O2. We describe the hierarchical regulation of Fe deficiency responses in the context of the opt3-2 mutant, and demonstrate that the opt3 dependent induction of Fe deficiency responses can be negated, or even reversed, by H2O2 dependent signaling, while the high Fe content of opt3-2 indicates Cd induced iron deficiency is not a function of reduced Fe uptake, but rather the putative leaf Fe sensor is Cd liable.

Project description:In muscle, reactive oxygen species (ROS) generation increases with strenuous activity, chronic unloading, and inflammatory stimuli; skeletal muscle function is very sensitive to ROS; and there are redox-sensitive signaling pathways. Using myogenic cell cultures, we asked whether hydrogen peroxide (H2O2) induces adaptive changes in skeletal muscle gene expression. H2O2 downregulated or failed to induce antioxidant or apoptotic genes in the myotubes. Instead, H2O2 changed the expression of genes for cytosolic and mitochondrial enzymes, and upregulated inflammatory mediators. Finally, H2O2 had a mostly inhibitory effect on the expression of many transcription factors. The results indicate that mild oxidative stress may induce an adaptive response in skeletal muscle without antioxidant upregulation or apoptosis. Keywords: Gene Expression, C2C12 Myotubes, Oxidative Stress, Adaptation

Project description:An important cellular defense mechanism against oxidative stress is the induction of genes involved in ROS resistance and DNA damage repair. Under normal conditions, Sod1 is localized mainly in the cytosol. However, we found that Sod1 translocates into the nucleus after oxidative stress. To address the physiological role of Sod1, we performed DNA microarray analysis of global gene expression in wild type (WT) and sod1M-NM-^T cells before and after treatment with H2O2. Early log phase WT and sod1M-NM-^T cells were treated with or without H2O2 for 20 min and RNA samples were extracted and subjected to hybridization on Affymetrix microarrays. We then compared the dataset of WT +/- H2O2 with SOD1 deleted cells +/- H2O2 to identify the H2O2-responsive genes whose induction was attenuated in sod1M-NM-^T cells by more than 50%.

Project description:Excessive levels of reactive oxygen species (ROS) cause cellular stress through damage to all classes of macromolecules and result in cell death. However, ROS can also act as signaling molecules in various biological processes. In plants, ROS signaling has been documented in environmental stress perception, plant development and cell death amongst others. Knowledge on the regulatory events governing ROS signal transduction is however still scratching the surface. To further elucidate the transcriptional response and regulation upon ROS accumulation we supplemented Arabidopsis seedlings with a 10mM hydrogen peroxide (H2O2) solution to trigger oxidative stress.

Project description:In Deinococcus radiodurans, a previously unreported special characteristic of DrOxyR (DR0615) is found with only one conserved cysteine. dr0615 gene mutant is hypersensitive to H2O2, but a little to ionizing radiation. Site-directed mutagenesis and subsequent in vivo functional analyses revealed that the conserved cysteine (C210) is necessary for sensing H2O2, but its mutation did not alter the binding characteristics of OxyR on DNA. Under oxidant stress, DrOxyR is oxidized to sulfenic acid form, which can be reduced by reducing reagents. In addition, quantitative real-time PCR and global transcription profile results showed that OxyR is not only a transcriptional activator (e.g., katE, drb0125), but also a transcriptional repressor (e.g., dps, mntH). Transcriptional profiling of comparing wildtype strains with oxyR disruption strains under normal growth conditions. Keywords: Genetic modification

Project description:Oxidative stress that originates from reactive oxygen species (ROS) is an inevitable consequence of aerobic respiration in bacteria. Three transcription factors (TFs), OxyR, SoxR, and SoxS play a critical role in transcriptional regulation of the defense system. However, the full genome-wide regulatory potential of them remains elusive. Here, we comprehensively reconstruct genome-wide OxyR, SoxR, and SoxS transcriptional regulatory networks in Escherichia coli under oxidative stress. Integrative data analysis reveals that OxyR, SoxR, and SoxS regulons are comprised of 38 genes in 28 transcription units (TUs), 11 genes in 10 TUs, and 34 genes in 25 TUs, respectively, significantly expanding the current knowledge of their regulatory networks. Comparison of them to other stress-response regulatory networks highlights minimal overlap between their regulons, indicating that E. coli has a series of relatively distinct stress responses covering the range of different stresses. We also demonstrate that these intricate networks coordinate detoxification process with DNA and protein damage repair, cell wall synthesis, divalent metal ion homeostasis, as well as metabolic robustness to produce overall response of E. coli to oxidative stress. A total of eight samples were analyzed. WT, ΔoxyR, ΔsoxR, and ΔsoxS mutant cells were cultured in M9 minimal media with 0.2% glucose. Then cells were treated with 250 uM of paraquat at mid-log pahse for 20 min with agitation.

Project description:Oxidative stress that originates from reactive oxygen species (ROS) is an inevitable consequence of aerobic respiration in bacteria. Three transcription factors (TFs), OxyR, SoxR, and SoxS play a critical role in transcriptional regulation of the defense system. However, the full genome-wide regulatory potential of them remains elusive. Here, we comprehensively reconstruct genome-wide OxyR, SoxR, and SoxS transcriptional regulatory networks in Escherichia coli under oxidative stress. Integrative data analysis reveals that OxyR, SoxR, and SoxS regulons are comprised of 38 genes in 28 transcription units (TUs), 11 genes in 10 TUs, and 34 genes in 25 TUs, respectively, significantly expanding the current knowledge of their regulatory networks. Comparison of them to other stress-response regulatory networks highlights minimal overlap between their regulons, indicating that E. coli has a series of relatively distinct stress responses covering the range of different stresses. We also demonstrate that these intricate networks coordinate detoxification process with DNA and protein damage repair, cell wall synthesis, divalent metal ion homeostasis, as well as metabolic robustness to produce overall response of E. coli to oxidative stress. A total of six samples were analyzed. oxyR-8myc, soxR-8myc, and soxS-8myc tagged cells were cultured in M9 minimal media with 0.2% glucose. Then cells were treated with 250 uM of paraquat at mid-log pahse for 20 min with agitation.