Project description:Peripheral blood lymphocytes from a total of 57 patients were immortalized with Epstein-Barr virus. Fourteen radiation-therapy patients suffered unusual levels of radiation toxicity (RadS). Thirteen radiation-therapy patients with limited toxicity (RadC) were enrolled as controls. Fifteen patients diagnosed with skin cancer before age 40 (SkCa) were used as a second group of controls. Fifteen healthy subjects without any history of cancer (NoCa) were matched to the skin cancer patients and used as a third group of controls. Cells were exposed to mock treatment (Mock), ultra-violet radiation (UV), or ionizing radiation (IR). For UV radiation treatment, cells were exposed to 10 J/m^2 and harvested for RNA 24 hours later. For IR treatment, cells were exposed to 5 Gy of IR and harvested for RNA 4 hours later. For example, RadS1-Mock refers to cells from radiation sensitive patient 1 exposed to mock treatment. The published manuscript (PNAS 101:6634, 2004) can be found at http://www.pnas.org/cgi/doi/10.1073/pnas.0307761101; Data were analyzed with Affymetrix MAS version 4.0. Normalization â?? A reference data set was generated by averaging the expression of each gene over all data sets. The data for each hybridization were compared with the reference data set in a cube root scatter plot. A linear least-squares fit to the cube root scatter plot was then used to normalize each hybridization.

Project description:Intraoperative radiotherapy (IOERT) is a high radiation therapeutic technique which administers a single high dose of ionizing radiation (IR) immediately after surgical tumor removal in order to destroy the residual cancer cells in the site at high risk for recurrence. IR is able to regulate several genes and factors involved in cell-cycle progression, survival and/or cell death, DNA repair and inflammation modulating an intracellular response radiation dependent producing an imbalance in cell fate decision. In this study, we examined changes in gene expression in MCF7 breast cancer cell line exposed to 9Gy and 23Gy high single dose of IR delivered by IOERT. Changes in gene expression in MCF7 breast cancer cell line exposed to 9Gy and 23Gy high single dose of IR (named MCF7_9Gy and MCF7_23Gy respectively), were analyzed as two-color hybridizations using Agilent Technologies whole human genome 4x44K microarrays

Project description:Intraoperative radiotherapy (IOERT) is a high radiation therapeutic technique which administers a single high dose of ionizing radiation (IR) immediately after surgical tumor removal in order to destroy the residual cancer cells in the site at high risk for recurrence. IR is able to regulate several genes and factors involved in cell-cycle progression, survival and/or cell death, DNA repair and inflammation modulating an intracellular response radiation dependent producing an imbalance in cell fate decision. In this study, we examined changes in gene expression in MCF7 breast cancer cell line exposed to 9Gy and 23Gy high single dose of IR delivered by IOERT.

Project description:Humans are exposed to ionizing radiation (IR) from background radiation, medical treatments, occupational and accidental exposures. IR causes profound changes in transcription. Transcription is a primary process where protein amount and function can be regulated. One aspect of the transcriptional IR response that little is known about on a whole genome basis is alternative transcription. These investigations focus on the response to IR at the exon level in human cells but also at the whole gene level. Whole genome exon arrays were utilized to comprehensively characterize radiation-induced transcriptional expression products in two human cell types, namely EBV-transformed lymphoblast and primary fibroblast cell lines.

Project description:Humans are exposed to ionizing radiation (IR) from background radiation, medical treatments, occupational and accidental exposures. IR causes profound changes in transcription. Transcription is a primary process where protein amount and function can be regulated. One aspect of the transcriptional IR response that little is known about on a whole genome basis is alternative transcription. These investigations focus on the response to IR at the exon level in human cells but also at the whole gene level. Whole genome exon arrays were utilized to comprehensively characterize radiation-induced transcriptional expression products in two human cell types, namely EBV-transformed lymphoblast and primary fibroblast cell lines. 12 human primary fibroblast cell lines and 12 primary lymphoblast cell line samples were used for two doses (0 and 10 Gy) and two time points (0 and 4hr). Additional doses ( 1 Gy, 2 Gy, 5 Gy, and 20 Gy) and time points ( 1hr, 2hr, 8hr, 24hr and 48hr) were assessed in four lymphoblast cell lines and four primary fibroblasts.

Project description:Peripheral blood lymphocytes from a total of 57 patients were immortalized with Epstein-Barr virus. Fourteen radiation-therapy patients suffered unusual levels of radiation toxicity (RadS). Thirteen radiation-therapy patients with limited toxicity (RadC) were enrolled as controls. Fifteen patients diagnosed with skin cancer before age 40 (SkCa) were used as a second group of controls. Fifteen healthy subjects without any history of cancer (NoCa) were matched to the skin cancer patients and used as a third group of controls. Cells were exposed to mock treatment (Mock), ultra-violet radiation (UV), or ionizing radiation (IR). For UV radiation treatment, cells were exposed to 10 J/m^2 and harvested for RNA 24 hours later. For IR treatment, cells were exposed to 5 Gy of IR and harvested for RNA 4 hours later. For example, RadS1-Mock refers to cells from radiation sensitive patient 1 exposed to mock treatment. The published manuscript (PNAS 101:6634, 2004) can be found at http://www.pnas.org/cgi/doi/10.1073/pnas.0307761101 Data were analyzed with Affymetrix MAS version 4.0. Normalization – A reference data set was generated by averaging the expression of each gene over all data sets. The data for each hybridization were compared with the reference data set in a cube root scatter plot. A linear least-squares fit to the cube root scatter plot was then used to normalize each hybridization. Keywords = Gene expression in lymphoid cells of cancer patients Keywords: repeat sample

Project description:It is elusive whether clonal selection of tumor cells in response to ionizing radiation (IR) is a deterministic or stochastic process. With high resolution clonal barcoding and tracking of over 400.000 HNSCC patient-derived tumor cells the clonal dynamics of tumor cells in response to IR was analysed. Fractionated IR induced a strong selective pressure for clonal reduction. This significantly exceeded uniform clonal survival probabilities indicative for a strong clone-to clone difference. within tumor cells. Survival to IR is driven by a deterministic clonal selection of a smaller population which commonly survives radiation, while increased clonogenic capacity is a result of clonal competition of cells which have been selected stochastically. The ratio of these parameters is amenable to radiation sensitivity which correlates to prognostic biomarkers of HNSCC. Evidence for the existence of a rare subpopulation with an intrinsically radiation resistant phenotype was found at a frequency of 0.6-3.3%. With cellular barcoding we introduce a novel functional heterogeneity associated qualitative readout for evaluating the contribution of stochastic and deterministic clonal selection processes in response to IR. To analyze transcriptomic changes of HNSCC cell lines after fractionated Photon IR (5x4Gy), RNAseq analysis was performed on irradiated cells in comparison to untreated control cells (EBI submission E-MTAB-9693)

Project description:Recent observations show that the single-cell response of p53 to ionizing radiation (IR) is “digital” in that it is the number of oscillations rather than the amplitude of p53 that shows dependence on the radiation dose. We present a model of this phenomenon. In our model, double-strand break (DSB) sites induced by IR interact with a limiting pool of DNA repair proteins, forming DSB–protein complexes at DNA damage foci. The persisting complexes are sensed by ataxia telangiectasia mutated (ATM), a protein kinase that activates p53 once it is phosphorylated by DNA damage. The ATM-sensing module switches on or off the downstream p53 oscillator, consisting of a feedback loop formed by p53 and its negative regulator, Mdm2. In agreement with experiments, our simulations show that by assuming stochasticity in the initial number of DSBs and the DNA repair process, p53 and Mdm2 exhibit a coordinated oscillatory dynamics upon IR stimulation in single cells, with a stochastic number of oscillations whose mean increases with IR dose. The damped oscillations previously observed in cell populations can be explained as the aggregate behavior of single cell

Project description:Insulin resistance (IR) is likely to induce metabolic syndrome and type 2 diabetes mellitus (T2DM). Gluconeogenesis (GNG) is a complex metabolic process that may result in glucose generation from certain non-carbohydrate substrates. Chinese herbal medicine astragalus polysaccharides and berberine have been documented to ameliorate IR, and combined use of astragalus polysaccharide (AP) and berberine (BBR) are reported to synergistically produce an even better effect. However, what change may occur in the GNG signaling pathway of IR-HepG2 cells in this synergistic effect and whether AP-BBR attenuates IR by regulating the GNG signaling pathway remain unclear. For the first time, we discovered in this study that the optimal time of IR-HepG2 cell model formation was 48 hours after insulin intervention. AP-BBR attenuated IR in HepG2 cells and the optimal concentration was 10mg. AP-BBR reduced the intracellular H2O2 content with no significant effect on apoptosis of IR-HepG2 cells. In addition, a rapid change was observed in intracellular calcium current of the IR-HepG2 cell model, and AP-BBR intervention attenuated this change markedly. The gene sequencing results showed that the GNG signaling pathway was one of the signaling pathways of AP-BBR to attenuate IR in IR-Hepg2 cells. The expression of p-FoxO1Ser256 and PEPCK protein was increased and the expression of GLUT2 protein was decreased significantly in the IR-HepG2 cell model, and both of these effects could be reversed by AP-BBR intervention. AP-BBR attenuated IR in IR-HepG2 cells, probably by regulating the GNG signaling Pathway.

Project description:The purpose of this study was to identify genes that were differentially expressed in radiation-sensitive, naïve HL60 cells, and the derivatives created in our laboratory as indicated in the 'sample title'. We wanted to identify genes that were differentially expressed both before and after ionizing radiation (IR) exposure, from both a single dose of gamma rays and a single dose of alpha particles, at 4h following IR exposure. The data were used to identify genes that could be driving radioresistance in each respective cell line. The four cell lines, HL60, RA11, RG8, and RV+ were all analyzed at control (0Gy) radiation dose, 8Gy gamma rays, and ~2Gy alpha particles. Samples were collected from each cell line, for each dose, 4h following radiation exposure. The samples were collected from three independent experiments from three consecutive days in cell culture.