Project description:Corynebacterium glutamicum was adapted in a chemostat for 1,900 h with gradually increasing H2O2 stress to understand the oxidative stress response of an industrial host. After 411 generations of adaptation, C. glutamicum developed the ability to grow under stress of 10 mM H2O2, whereas the wild-type did not. The adapted strain also showed increased stress resistance to diamide and menadione, SDS, Tween 20, HCl, NaOH, and ampicillin. A total of 1,180 genes in the RNA-seq transcriptome analysis of the adapted strain were up-regulated twice or higher (corresponding to 38.6 % of the genome), and 126 genes were down-regulated half or less (4.1 % of genome) under 10 mM H2O2-stress conditions compared with those of the wild-type under a no stress condition. Especially the aromatic compound-degrading gene clusters (vanRABK, pcaJIRFLO, and benABCDRKE) were more than threefold up-regulated. Plausible reasons for the H2O2-stress tolerance of the adapted strain are discussed as well as the potential strategy for development of oxidative stress-tolerant strain.

Project description:Green plants are more robust to hydrogen peroxide (H2O2) stress and contain high endogeneous H2O2 levels which is generated during photorespiration and photosynthesis. Therefore, exgeneous H2O2 application mostly impose oxidative stress. To reduce endogenous H2O2 background, we adopted a strategy which is to grow Arabidopsis seedlings in the dark to eliminate light-induced H2O2 production, thus to reduce the endogenous H2O2 level. Exogenous H2O2 was then applied to induce transcriptome changes. Global gene expression is studied and compared between samples collected under 7d dark, 7d H2O2 treatment under dark and 7d light conditions.

Project description:Organisms frequently experience environmental stresses that occur in predictable patterns and combinations. For wild Saccharomyces cerevisiae yeast growing in natural environments, cells may experience high osmotic stress when they first enter broken fruit, followed by high ethanol levels during fermentation, and then finally high levels of oxidative stress resulting from respiration of ethanol. Yeast have adapted to these patterns by evolving sophisticated “cross protection” mechanisms, where mild ‘primary’ doses of one stress can enhance tolerance to severe doses of a different ‘secondary’ stress. For example, in many yeast strains, mild osmotic or mild ethanol stresses cross protect against severe oxidative stress, which likely reflects an anticipatory response important for high fitness in nature. During the course of genetic mapping studies to understand the mechanisms underlying natural variation in ethanol-induced cross protection against H2O2, we found that a key H2O2 scavenging enzyme, cytosolic catalase T (Ctt1p), was absolutely essential for cross protection in a wild oak strain, suggesting the absence of compensatory mechanisms for acquired H2O2 resistance under that condition. In this study, we found surprising heterogeneity across diverse yeast strains in whether CTT1 function was fully necessary for acquired H2O2 resistance. Some strains exhibited partial dispensability of CTT1 when ethanol and/or salt were used as mild stressors, suggesting that compensatory peroxidases may play a role in acquired stress resistance in certain genetic backgrounds. We leveraged global transcriptional responses to ethanol and salt stresses in strains with different levels of CTT1 dispensability, allowing us to identify possible regulators of these alternative peroxidases and acquired stress resistance in general. Ultimately, this study highlights how superficially similar traits can have different underlying molecular foundations and provides a framework for understanding the diversity and regulation of stress defense mechanisms.

Project description:Thiol peroxidase (TpxD) is one of the key enzymes used to cope with oxidative stress conditions in S. pneumoniae. Previously, we demonstrated that TpxD expression is modulated in response to H2O2 and is involved in the regulation of the psa operon. In the current study, we focus on TpxD function as a sensor and global regulator in the bacterial response to H2O2. By using microarray assays, we show that TpxD expression is necessary for the activation of bacterial global gene response to H2O2. The mechanism underlying TpxD regulatory function was further elucidated by replacing the catalytic cysteine (Cys58) with alanine (Ala58) in TpxD. This point mutation prevented tpxD up-regulation by H2O2, as well as the effect of H2O2 on additional genes that were affected by H2O2 in the WT but not in ∆tpxD, signifying that this cysteine is crucial for TpxD signaling activity. We then tried to identify a candidate transcription factor which regulates tpxD expression under H2O2 stress. Bioinformatics analysis identified a putative CodY 15 bp binding site in the proximal upstream region of tpxD coding sequence. Genetic engineering techniques and EMSA assays confirmed the presence of an active CodY box. Indeed, no up-regulation of TpxD was noticed in ∆codY challenged with H2O2. These data identify CodY as the transcription factor modulating tpxD expression under H2O2 stress. We propose a model of gene regulation under oxidative stress conditions which places TpxD as an intermediary between H2O2 and the global bacterial response to oxidative stress. This SuperSeries is composed of the SubSeries listed below.

Project description:DNA methylation is an important regulatory mechanism that contributes to transcriptional repression. To examine whether DNA methylation affects the transcriptional changes of DNA repair genes under H2O2-induced oxidative stress, we performed reduced representation bisulfite sequencing (RRBS) in H2O2-treated and untreated HCT116 cells.

Project description:We performed tRNAome sequencing to assess the tRNA changes of E.coli under oxidative stress. We found that the global translation inhibition is caused by global down-regulation of almost all tRNA species under oxidative stress. The translation elongation speed is resumed after the cells are fully adapted to the oxidative environment.

Project description:Oal anaerobic bacteria have to face constant oxidative stress in order to survive in the inflammatory environment of the periodontal pocket. In this study, we analyzed the transcriptome profiles of P. gingivalis and Filifactor in monoculture as compared to P. gingivalis+F.alocis coculture under H2O2 stress condtions, to analyze the genes responsible for enhanced survival of P. gingivalis in presence of F. alocis under oxidative-stress conditions.

Project description:We aimed to identify putative H2O2-regulated miRNAs expressed in rice seedlings under oxidative stress by using a deep sequencing approach developed by Solexa (Illumina). Two small RNA libraries were constructed from H2O2-treated and control rice seedlings, and more than five million small RNA sequence reads were generated for each library. We identified seven H2O2-responsive miRNA families via expression profiling of the miRNAs based on a comparative miRNAomic analysis in combination with experimental validation. Furthermore, 32 miRNAs, 17 from known miRNA loci and 15 from novel miRNA loci, were also newly identified from the sequencing data. To the best of our knowledge, this is the first report of a systematic investigation of H2O2-regulated miRNAs and their targets in plants. Examination of 2 different small RNA expression profilings in the control and H2O2 treated rice samples.

Project description:Long non-coding RNAs (lncRNAs) exhibit a poor interspecies conservation and often show spatial- and temporal-specific expression patterns. What, if any, role they have in oxidative stress remains unknown. To identify potential roles for lncRNAs, we examined their expression in normal and H2O2-treated human umbilical vein endothelial cells. Oxidative stress related lncRNAs were generated by deep sequencing, using Illumina HiSeq 2000 or 2500 platform. Sequencing of the cDNA libraries from H2O2-treated HUVECs generated 12.5 million uniquely valid reads, meanwhile, 10.2 million valid fragments were obtained from control group in our experiment. A total of 10, 765 known and 30, 629 novel putative lncRNAs were identified according to RNA-Seq. Among them, 2, 091 of known and 25, 800 of novel lncRNAs were differentially expressed in H2O2-treated HUVECs compared with control HUVECs, and 12 of these were validated with qRT–PCR. Taken together, our findings provide evidence differentially expressed lncRNAs were mediated by oxidative stress in HUVECs, it is, therefore, likely that aberrant expression of lncRNAs, at least in part, participate in the process of endothelial injury caused by oxidative stress. Examination of lncRNAs in the oxidative-stressed human umbilical vein endothelial cells

Project description:Snt2 is a yeast chromatin-interacting protein whose function has not been well characterized, that was recently shown to associate with Ecm5 and the Rpd3 deacetylase. Using chromatin immunoprecipitation followed by high-throughput sequencing (ChIP-seq), we show that in response to H2O2, Snt2 and Ecm5 colocalize to promoters of genes involved in various aspects of the environmental stress response. By integrating these ChIP-seq results with expression analysis, we identify a key set of target genes that require Snt2 for proper expression after H2O2 stress. Finally, by mapping Snt2 and Ecm5 localization before and after rapamycin treatment, we identify a subset of H2O2-specific Snt2 and Ecm5 target promoters that are also targeted in response to rapamycin. Our results establish a function for Snt2 in regulating transcriptional changes in response to oxidative stress, and suggest Snt2 may have a role in additional stress pathways. Crosslinking ChIP analysis to identify sites of Snt2 or Ecm5 genomic localization before, 0.5 hours after, or 4 hours after treatment with H2O2 (final concentration 0.4 mM). Snt2 and Ecm5 were genomically tagged with a 13Myc tag at their C termini. ChIPs were performed using a Myc antibody on either Snt2-Myc or Ecm5-Myc strains, or on an untagged wildtype strain (BY4741) as a control. Inputs and ChIPs from untagged strain were sequenced as controls.