Transcription profiling of anaerobic transcriptional response of E.coli MG1655 to NO released from NOC compounds
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ABSTRACT: The transcriptional response of Escherichia coli MG1655 to NO released from NOC-5 and NOC-7 under anerobic conditions in contiuous chemostat culture on chemically defined minimal media
Project description:Escherichia coli strain MG1655 response to NO released from NOC compounds. Under contiuous steady state chemostat conditions, in chemically defined media.
Project description:This SuperSeries is composed of the following subset Series: GSE38114: Exposure of microaerobic Campylobacter jejuni to 10 micromolar NOC-5 & NOC-7 GSE38115: Exposure of oxygen limited Campylobacter jejuni to 10 micromolar NOC-5 & NOC-7 Refer to individual Series
Project description:Oxygen transition experiement. Chemostat initially at steady state under oxygen replete conditions (7.5% oxygen input) was perturbed by a reduction in oxygen input (to 1.88% oxygen input). Samples were taken at the 7.5% oxygen and new 1.88% oxygen steady-states and at various points during the transtion between 7.5% and 1.88% oxygen. Type II experiment Biological replicates: At least 3 of each time point. Three independent transition experiements were performed. All samples were analysed with 7.5% oxygen as the reference. gDNA for Cy3 channel from wild-type strain.
Project description:N-nitroso compounds (NOC) may be implicated in human colon carcinogenesis, but the toxicological mechanisms involved have not been elucidated. Since it was previously demonstrated that nitrosamines and nitrosamides, representing two classes of NOC, induce distinct gene expression effects in colon cells that are particularly related to oxidative stress, we hypothesized that different radical mechanisms are involved. Using ESR spectroscopy, we investigated radical generating properties of genotoxic NOC concentrations in human colon adenocarcinoma cells (Caco-2). Cells were exposed to nitrosamides (N-methyl-N'-nitro-N-nitrosoguanidine, N-methyl-N-nitrosurea) or nitrosamines (N-nitrosodiethylamine, N-nitrosodimethylamine, N-nitrosopiperidine, N-nitrosopyrrolidine). Nitrosamines caused formation of reactive oxygen species (ROS) and carbon centered radicals which was further stimulated in presence of Caco-2 cells. N-methyl-N-nitrosurea exposure resulted in a small ROS signal, and formation of nitrogen centered radicals (NCR), also stimulated by Caco-2 cells. N-methyl-N'-nitro-N-nitrosoguanidine did not cause radical formation at genotoxic concentrations, but at increased exposure levels, both ROS and NCR formation was observed. By associating gene expression patterns with ROS formation, several cellular processes responding to nitrosamine exposure were identified, including apoptosis, cell cycle blockage, DNA repair and oxidative stress. These findings suggest that following NOC exposure in Caco-2 cells, ROS formation plays an important role in deregulation of gene expression patterns which may be relevant for the process of chemical carcinogenesis in the human colon, in addition to the role of DNA alkylation. Keywords: Nitrosamines, nitrosamides, N-nitroso compounds, free radicals, toxicogenomics, colon carcinogenesis The study investigated differential gene expression in Caco-2 cell line mRNA following 1, 6 or 24 hours of exposure to six different N-nitroso compounds. Two biological replicates per sample compound. One compound per array, hybridized against vehicle control. Dye-swap between biological replicates.
Project description:Peroxynitrite is formed in macrophages by the diffusion-limited reaction of superoxide and nitric oxide. This highly reactive species is capable of causing both oxidative and nitrosative stress in Escherichia coli. Previous studies have focused on the reactions of peroxynitrite with specific proteins or the effects of peroxynitrite on the growth and viability of whole cells. This work shows for the first time the transcriptomic response of E. coli to peroxynitrite, highlighting specific areas targeted by the stress. Upregulation of the cysteine biosynthesis pathway and subsequent identification of an increase in S-nitrosothiol levels suggests S-nitrosylation as a consequence of peroxynitrite exposure. Genes involved in the assembly / repair of iron-sulfur clusters also show enhanced transcription identifying another target of this reactive species. Unexpectedly arginine biosynthesis gene transcription levels were also elevated after treatment with peroxynitrite. Analysis of the negative regulator for these genes, ArgR, showed that the post-translational nitration of tyrosine residues within this protein is responsible for its degradation in vitro. Further upregulation is seen in oxidative stress response genes including katG and ahpCF. Probabilistic modelling of this data identified 5 altered transcription factors in response to peroxynitrite exposure including OxyR and ArgR. Hydrogen peroxide can be present as a contaminant in commercially available peroxynitrite preparations. Transcriptomic analysis of cells treated with hydrogen peroxide also showed an upregulation of oxidative stress response genes; however it did not show increased transcription of many other genes which are upregulated by peroxynitrite suggesting that cellular responses to peroxynitrite and hydrogen peroxide are distinct. Biological experiments (i.e. a comparison of control and plus peroxynitrite cells) were carried out three times, and a dye swap performed for each experiment, providing two technical repeats for each of the three biological repeats. Data from the independent experiments were combined. Genes that were differentially expressed ≥ twofold and displayed and P value of < 0.05 (as determined by a t test) were defined as being statistically significantly differentially transcribed. Additional biological experiments (i.e. a comparison of control and plus hydrogen peroxide cells) were carried out three times, and a dye swap performed for each experiment, providing two technical repeats for each of the three biological repeats. Data from the independent experiments were combined. Genes that were differentially expressed ≥ twofold and displayed and P value of < 0.05 (as determined by a t test) were defined as being statistically significantly differentially transcribed.
Project description:CD3-positive T cells were negatively isolated from 10 SLE patients and 9 healthy controls without SLE. All of the SLE samples and control samples were compared with one another to identify baseline differences in expression due to the disease. Next, T cell preparations from 4 of the control subjects were stimulated with either Nitric Oxide (NOC-18) 600 uM for 24hr or stimulated through CD3/CD28 for 24hr to determine which genes were responsive to these signaling mechanisms. Here, we show that activity of the mammalian target of rapamycin (mTOR), which is a sensor of the mitochondrial transmembrane potential, is increased in SLE T cells. Activation of mTOR was inducible by NO, a key trigger of MHP which in turn enhanced the expression of HRES-1/Rab4, a small GTPase that regulates recycling of surface receptors through early endosomes. Expression of HRES-1/Rab4 was increased in SLE T cells and, in accordance with its dominant impact on the endocytic recycling of CD4, it was inversely correlated with diminished CD4 expression. HRES-1/Rab4 over-expression was also inversely correlated with diminished TCRζ protein levels. Combined with follow up studies, these results suggest that activation of mTOR causes the loss of TCRζ in lupus T cells through HRES-1/Rab4-dependent lysosomal degradation. Experiment Overall Design: 10 replicate T cell samples from SLE (Lupus) patients Experiment Overall Design: 9 replicate T cell samples from healthy control (BC) subjects Experiment Overall Design: 4 replicate Nitric Oxide (NOC-18) stimulated T cell samples from 4 of the control subjects Experiment Overall Design: 4 replicate CD3/CD28 stimulated T cell samples from 4 of the control subjects
Project description:Two batch cultures of Wild-type C. jejuni NCTC 11168 were grown in 100 ml volumes of Mueller-Hinton broth in 250 ml baffled flasks. Microaerophilic conditions were generated using a MACS-VA500 microaerophilic work station (10 % Oxygen, 10 % Carbon dioxide, 80 % Nitrogen) from Don Whitley Scientific, Ltd which also maintained the growth temperature at 42 M-BM-:C. When mid-exponential phase was reached 0.010 mM NOC-5 & NOC-7 was added to one of the cultures. After a 15 minute exposure samples of both treated and untreated cells were harvested into phenol/ethanol to stabilize the RNA and total RNA was purified using QiagenM-bM-^@M-^Ys RNeasy Mini kit (as recommended by the suppliers) prior to use in microarray analysis. Batch cultures of Wild-type C. jejuni NCTC 11168 were grown in 100 ml volumes of Mueller-Hinton broth in 250 ml baffled flasks. Microaerophilic conditions were generated using a MACS-VA500 microaerophilic work station (10 % Oxygen, 10 % Carbon dioxide, 80 % Nitrogen) from Don Whitley Scientific, Ltd which also maintained the growth temperature at 42 M-BM-:C. When mid-exponential phase was reached 0.25 mM GSNO was added to half of the cultures. After a 10 minute exposure, 30 ml samples of both treated and untreated cells were mixed immediately on ice with 3.56 ml 100% ethanol and 185 M-BM-5l phenol to stabilize the RNA. The cells were subsequently harvested by centrifugation. Total RNA was purified by using a Qiagen RNeasy Mini kit as recommended by the supplier. Equivalent amounts of RNA (15 M-NM-<g) from control and test cultures were used as template for synthesis of labelled cDNA. Labelling was done by using dCTP nucleotide analogues containing either Cy3 or Cy5 fluorescent dyes. RNA was primed with 9 M-NM-<g pd(N)6 random hexamers (Amersham Biosciences). For annealing, the mixture was incubated for 10 min at 65oC and then 10 min at room temperature. Each reaction mixture (0.5 mM dATP, dTTP and dGTP, 0.2 mM dCTP, 0.1 mM DTT (Invitrogen) and 1 mM Cy3-dCTP or Cy5-dCTP, total volume 25ul) was incubated for 3 h at 42 oC with 200 U of Superscript III RNase-H Reverse Transcriptase (Invitrogen). The reaction was terminated by the addition of 5u1 mM NaOH and heating the tube to 65 oC for 10 min to hydrolyse the RNA. Then it was neutralised with 5ul 1M HCl and 1 M TE (pH 8). Purification of cDNA was done with a PCR purification kit (Qiagen). The cDNA was eluted and resuspended in 30 M-NM-<l elution buffer (Qiagen, supplied in kit). Each slide set (control slide and dye-swap) was prepared as follows: For control slide Cy3-dCTP labelled control cDNA was mixed with Cy5-dCTP labelled test cDNA. For dye-swap slide Cy5-dCTP labelled control cDNA was mixed with Cy3-dCTP labelled test cDNA. This is made for compensate possible differences in the labelled nucleotides incorporation. The slides used were C. jejuni OciChipM-BM-. arrays from Ocimum Biosolutions. The cDNA mixture for each slide was dried by evaporation for approximately 35 min in a SPD 121P SpeedVacM-BM-. (Thermo Savant, Waltham, MA, USA) The dry cDNA was resuspended in pre-warmed (42M-BM-:C) salt-based hybridisation buffer (Ocimum Biosolutions) and was heated to 95 M-BM-0C for 3 min and then placed on ice for 3 min. The spoted area of the slide (located with an array finder) was enclosed within a gene frame (MWG/Ocimum). The cDNA suspension was distributed through the inner space of the gene frame and enclosed with an air-tight coverslip. The slides were incubated for 16-24 hours at 42M-BM-: C in sealed MWG hybridisation chambers shaken in a water bath. After incubation, gene frames and coverslips were removed and slides washed sequentially in 2x, 1x, 0.2x y 0.1x SSC buffer, by shaking for 5 minutes at 80 rpm at 37M-BM-: C pre-warmed buffer. (2x buffer was supplemented with 1% SDS). Then the slides were dried by centrifugation at 250 x g for 5 min. Slides were scanned using an Affymetrix 428 scanner. The processing of images and quantification of the microarrays signal was done using software from Biodiscovery Inc (Imagene, version 4.0 and Genesight, version 4.0). Spots with signal intensity lower than background or other significant blemishes were eliminated from subsequent processing. Mean values from each channel were then log2 transformed and normalised using the Subtract by Mean method to remove intensity-dependent effects in the log2 (ratios) values. The Cy3/Cy5 fluorescent ratios were calculated from the normalised values. Significance analysis of the data used the StudentM-bM-^@M-^Ys t test to determine the probability that the average of the experimental replicates was significantly different from the average of the control replicates. p-values for the data were calculated by treating each slide as a repeat using Genesight 4. Genes differentially regulated M-bM-^IM-% 2-fold and displaying a p-value of M-bM-^IM-$ 0.05 were defined as being statistically significant and differentially transcribed.