Project description:Background: Radiation exposure due to the detonation of an improvised nuclear device remains a major security concern. Radiation from such a device involves a combination of photons and neutrons. Although photons will make the greater contribution to the total dose, neutrons will certainly have an impact on the severity of the exposure as they have high relative biological effectiveness. Results: We investigated the gene expression signatures in the blood of mice exposed to 3 Gy x-rays, 0.75 Gy of neutrons, or to mixed field photon/neutron with the neutron fraction contributing 5%, 15%, or 25% of a total 3 Gy radiation dose. Gene ontology and pathway analysis revealed that genes involved in protein ubiquitination pathways were significantly overrepresented in all radiation doses and qualities. On the other hand, eukaryotic initiation factor 2 (EIF2) signaling pathway was identified as one of the top 10 ranked canonical pathways in neutron, but not pure x-ray, exposures. In addition, the related mTOR and regulation of EIF4/p70S6K pathways were also significantly underrepresented in the exposures with a neutron component, but not in x-ray radiation. The majority of the changed genes in these pathways belonged to the ribosome biogenesis and translation machinery and included several translation initiation factors (e.g. Eif2ak4, Eif3f), as well as 40S and 60S ribosomal subunits (e.g. Rsp19, Rpl19, Rpl27). Many of the differentially downregulated ribosomal genes (e.g. RPS19, RPS28) have been causally associated with human bone marrow failure syndromes and hematologic malignancies. We also observed downregulation of transfer RNA processes, in the neutron-only exposure (p < 0.005). Ingenuity Pathway Analysis (p < 0.05) of differentially expressed genes predicted significantly suppressed activity of the upstream regulators c-Myc and Mycn, transcription factors known to control ribosome biogenesis. Conclusions: We describe the gene expression profile of mouse blood following exposure to mixed field neutron/x-ray irradiation. We have discovered that pathways related to protein translation are significantly underrepresented in the exposures containing a neutron component. Our results highlight the significance of neutron exposures that even the smallest percentage can have profound biological effects that will affect medical management and treatment decisions in case of a radiological emergency.

Project description:The detonation of an improvised nuclear device would produce prompt radiation consisting of both photons (gamma-rays) and neutrons. While much effort in recent years has gone into the development of radiation biodosimetry methods suitable for mass triage, the possible effect of neutrons on the endpoints studied has remained largely uninvestigated. We have used a novel neutron irradiator with an energy spectrum based on that 1-1.5 km from the epicenter of the Hiroshima blast to begin examining the effect of neutrons on global gene expression, and the impact this may have on the development of gene expression signatures for radiation biodosimetry. We have exposed peripheral blood from healthy human donors to 0, 0.1, 0.3, 0.5, or 1 Gy of neutrons ex vivo using our neutron irradiator, and compared the transcriptomic response 24 h later to that resulting from exposure to 0.1, 0.3, 0.5, 1, 2 or 4 Gy of photons (x-rays).

Project description:Background: In the event of an improvised nuclear device detonation, the prompt radiation exposure would consist of γ rays plus a neutron component that would contribute to the total dose. As neutrons cause more complex and difficult to repair damage to cells that would result in more severe health burden to affected individuals, it is paramount to be able to estimate the contribution of neutrons to an estimated dose, to provide information for those making treatment decisions. Results: Mice exposed to either 0.25 or 1 Gy of neutron or 1 or 4 Gy x-ray radiation were sacrificed at 1 or 7 days after exposure. Whole genome microarray analysis identified 7,285 and 5,045 differentially expressed genes in the blood of mice exposed to neutron or x-ray radiation, respectively. Neutron exposure resulted in mostly downregulated genes, whereas x-rays showed both down- and up-regulated genes. A total of 34 differentially expressed genes were regulated in response to all ≥1 Gy exposures at both times. Of these, 25 genes were consistently downregulated at days 1 and 7, whereas 9 genes, including the transcription factor E2f2, showed bi-directional regulation; being downregulated at day 1, while upregulated at day 7. Gene ontology analysis revealed that genes involved in nucleic acid metabolism processes were persistently downregulated in neutron irradiated mice, whereas genes involved in lipid metabolism were upregulated in x-ray irradiated animals. Most biological processes significantly enriched at both timepoints were consistently represented by either under- or over-expressed genes. In contrast, cell cycle processes were significant among down-regulated genes at day 1, but among up-regulated genes at day 7 after exposure to either neutron or x-rays. Cell cycle genes downregulated at day 1 were mostly distinct from the cell cycle genes upregulated at day 7. However, five cell cycle genes, Fzr1, Ube2c, Ccna2, Nusap1, and Cdc25b, were both downregulated at day 1 and upregulated at day 7. Conclusions: We describe, for the first time, the gene expression profile of mouse blood cells following exposure to neutrons. We have found that neutron radiation results in both distinct and common gene expression patterns compared with x-ray radiation.

Project description:Carbon-ion irradiation is an emerging therapeutic option for several tumor entities including lung cancer. Well oxygenated tumor areas compared to a hypoxic environment favor therapeutic photon irradiation efficiency of solid tumors due to increased amounts of DNA damage. The resistance of hypoxic tumor areas towards photon irradiation is enhanced through increased HIF-1 signaling. Here, we compared the effects of oxygen and HIF 1 after photon and carbon-ion irradiation with biological equivalent doses in a human non-small lung cancer model. In hypoxia compared to normoxia, A549 and H1299 cells displayed improved survival after photon irradiation. Knockdown of HIF-1M-NM-1 combined with photon irradiation synergistically delayed tumor growth in vivo. Photon irradiation induced HIF-1M-NM-1 and several of its target genes such as PDK1, GLUT-1, LDHA, and VEGF with subsequent enhanced tumor angiogenesis in vivo, a signaling cascade that was not targeted by carbon-ion irradiation. We present evidence that photons but not carbon-ions induce HIF-1M-NM-1 via mTOR pathway. Importantly, after carbon-ion irradiation in vivo, we observed substantial downregulation of HIF-1M-NM-1 and a drastically delayed tumor growth indicating a considerable higher relative biological effectiveness (RBE) than anticipated from the cell survival data. In sum, our results demonstrate that carbon-ions mediate an improved therapeutic response of tumor treatment compared to photon irradiation that is independent of cell oxygenation and HIF-1 signaling. 16 independent cell cultures were used. Each culture was split into an irradiated and a control plate, yieldin a total of 16 paired samples. Paired samples were analysed in 16 two-color hybridizations. Factors time (after irradiation) with levels 1h and 4h and factor radiation quality with levels C12 and X-rays were analyzed. Each of the 2x2 combinations was analyzed in 4 independent experiments.

Project description:Gene expression response in human peripheral blood exposed to mixed neutron-photon radiation ex vivo

Project description:Carbon-ion irradiation is an emerging therapeutic option for several tumor entities including lung cancer. Well oxygenated tumor areas compared to a hypoxic environment favor therapeutic photon irradiation efficiency of solid tumors due to increased amounts of DNA damage. The resistance of hypoxic tumor areas towards photon irradiation is enhanced through increased HIF-1 signaling. Here, we compared the effects of oxygen and HIF 1 after photon and carbon-ion irradiation with biological equivalent doses in a human non-small lung cancer model. In hypoxia compared to normoxia, A549 and H1299 cells displayed improved survival after photon irradiation. Knockdown of HIF-1α combined with photon irradiation synergistically delayed tumor growth in vivo. Photon irradiation induced HIF-1α and several of its target genes such as PDK1, GLUT-1, LDHA, and VEGF with subsequent enhanced tumor angiogenesis in vivo, a signaling cascade that was not targeted by carbon-ion irradiation. We present evidence that photons but not carbon-ions induce HIF-1α via mTOR pathway. Importantly, after carbon-ion irradiation in vivo, we observed substantial downregulation of HIF-1α and a drastically delayed tumor growth indicating a considerable higher relative biological effectiveness (RBE) than anticipated from the cell survival data. In sum, our results demonstrate that carbon-ions mediate an improved therapeutic response of tumor treatment compared to photon irradiation that is independent of cell oxygenation and HIF-1 signaling.

Project description:Ionizing radiations are categorized by linear energy transfer (LET) into low-LET and high-LET. High-LET is considered to have a higher relative biological effectiveness (RBE) than low-LET radiations. However, the details of the effects have not been clearly determined. The aim of this study was to characterize the difference between high-LET and low LET radiations. The global effects of the three types of high-LET radiations (fast neutron, heavy ion (C) and thermal neutron) were compared with the low-LET radiation (gamma ray) using yeast DNA microarrays. Highly induced genes by the three types of high-LET radiations were those genes related to oxidative stress. Oxidative stress was one of the common factors associated with the four types of radiations. Oxidative stress induced by high-LET radiations may be more serious than that induced by gamma rays. Additionally, genes related to protein synthesis and the ubiquitin and proteasome system were detected. This suggests that more protein damages can be induced by high-LET radiation that denatures the proteins in yeast cells. The genes specifically altered by each type of high-LET radiation were also studied. Keywords: stress response

Project description:The objective of this investigation was to characterize, at individual level, the transcriptional response and the onset of regenerative processes in mouse skin irradiated with different doses of fast neutrons. We performed a high-throughput gene expression analysis, by DNA oligonucleotide microarray on 24 three months old C57Bl/6 mice irradiated with 0, 0,2 and 1 Gy of mono-energetic 14 MeV neutron. The results, partially validated by quantitative real time RT-PCR, showed an up-regulation of a sub-class of keratin and keratin associated proteins, and of components of the S100 family of Ca2+-binding proteins which was limited to the lower dose. We conclude that the dose-dependent differential gene expression, reminiscent of the onset of re-epithelialization and wound healing, depends upon the proportion of cells carrying multiple lesions at chromosomal level post-irradiation, and it represents an in vivo evidence of a skin regenerative program exerted independently from DNA repair-associated pathways. Four condition experiment: 6h and 24h from 0.2 Gy neutron irradiation; 6h and 24 from 1 Gy neutron irradiation. One replicate for each condition

Project description:Low-LET radiation can cause cardiovascular dysfunctions at high-dose rates. For example, photons used in thoracic radiotherapy are known to cause acute cardiac tissue damage with elevated serum cardiac Troponin I level and long-term cardiac complications when delivered as fractionated exposures at high-dose rates. However, the effects of continuous low-dose rate radiation exposure on the heart, which simulate the space radiation environment, have not been well-studied. In this study, we aim to model low-LET space radiation-induced cardiovascular dysfunction using human induced pluripotent stem cell (iPSC)-derived engineered heart tissues (EHTs) exposed to protracted γ-ray irradiation. The investigation of pathophysiological changes in this model may provide insights and guide the development of countermeasures. As a proof-of-principle for the application of this model in drug development, we also tested the protective effect of a mitochondrial-specific antioxidant, MitoTempo, on irradiated EHTs.

Project description:In the present study approximately 1 to 2 mm3 prostate tumor AT1 was inoculated subcutaneously in the right hind leg of adult male Copenhagen rats. When the tumor diameter exceeded 15 mm, tumors of 5 and 4 rats were irradiated with carbon ion radiation of 37 or 16Gy respectively. Tumors of 5 other rats were irradiated with photon radiation of 37Gy. One animal irradiated with 37 Gy carbon ion radiation and one animal irradiated with photon radiation was sacrificed 12h, 30h, 72h, 7d and 14d after irradiation respectively. One animal irradiated with 16 Gy photon radiation was sacrificed 12h, 60h, 7d and 14d after irradiation respectively. Non-irradiated animals were sacrificed at 60h time point. Tumors were dissected and frozen in liquid nitrogen immediately. Total RNA from tumor material was isolated using the NucleoSpin RNA L kit (#740962.20, Macherey-Nagel). Differential gene expression analysis was performed on the Agilent whole rat genome Oligo Microarray (44k) platform by comparative two dye hybridisation with dye-swaps.