Distinct transcriptome profiles in response to low-LET and high-LET and different radiation qualities of HZE particles. Total RNA obtained from HBEC3KT cells after 1 4 12 and 24 hours of radiation. Mock-irradiated samples at each time point and control samples before radiation (0 hour) were also collected.

The aim of our research is to clarify the mechanisms generating heterogeneity in response to C-ion irradiation that arise from individual genetic variations in humans. In this study we performed whole lung C-ion irradiation using three different strains of mice to examine whether strain-dependent differences in radiation effects occur in high-LET C-ion thoracic irradiation. Murine strain-variance was evaluated by histopathological examination of intra-alveolar hemorrhage that is likely to occur during the early phase after irradiation and of lung fibrosis during the late phase occurring more than three months after irradiation. We also performed microarray analysis to identify the key genes that are differentially regulated in different mouse strains after C-ion irradiation and to determine the mechanism of strain-dependent pulmonary damage after high-LET C-ion irradiation. Eight-week old female inbred C3H/He Slc C57BL/6J Jms Slc and A/J Jms Slc mice (3 kinds of mice) were used. The whole thorax of three mice was locally irradiated at 10 Gy with C-ion beams with a reference beam 137Cs gamma-rays (2 kinds of beam). Three mice of each strain (3 mice) were sacrificed and immediately dissected for lung extraction at 6 h (6h sample). Lungs for three mice of each strain without irradiation were extracted at the same time as control samples (control sample). Hybridization to microarrays (Whole Mouse Genome 4x44K OligoMicroarray Kit single color Cyamine 3-CTP) consisting of 44,000 total spots was conducted using an Agilent Gene Expression hybridization kit. The arrays from three independent replicates for each sample (3 arrays) were scanned on an Agilent dual-laser Microarray Scanner (all from Agilent Technologies) following the manufacturer s instructions. A total of 108 samples were analyzed. 3 replicate arrays x 3 mice x 3 strains x 2 timing for sampling x 2 kinds of beam.

Here we present a whole-genome survey of the murine transcriptomic response to physiologically-relevant radiation doses 2 and 8 Gy. There are 18 distinct biological samples here. Mice were exposed to ionizing radiation (Cesium-138 source) and whole blood was collected by cardiac puncture 6 hours post treatment. Doses were 0 (7 samples) 2 (5 samples) and 8 (6 samples) gy.

Understanding the possible impact of potential confounding factors is necessary for any approach to radiation biodosimetry. Potential confounding factors have not been fully addressed for gene expression-based biodosimetry approaches such as we are developing. To begin addressing this need we have used an ex vivo irradiated peripheral blood cell model to investigate the potential effect of smoking on the global radiation gene expression response and looked for genes that respond to radiation differently in smokers and non-smokers and also in males and females. The results indicate that only a small number of genes may be significantly confounded by either factor supporting the idea of developing peripheral blood gene expression strategies for radiation biodosimetry. Blood from each of 24 different donors was exposed to four doses of ionizing radiation (0 0.1 0.5 or 2 Gy) and analyzed using single-color microarray hybridization. The donors represented equal numbers of male and female smokers (1 or more packs a day) and non-smokers. There are 95 data sets in the study as the sample from one of the female smokers exposed to 2 Gy was lost.

Accumulating data suggest that the biological responses to high and low doses of radiation are qualitatively different necessitating the direct study of low dose responses. Most such studies have utilized 2-dimensional culture systems which may not fully represent responses in 3-dimensional tissues. To gain insight into low dose responses in tissue we have profiled global gene expression in EPI-200 a 3-dimensional tissue model from MatTek that imitates the structure and function of human epidermis at 4 16 and 24 hours after exposure to high (2.5 Gy) and low (0.1 Gy) doses of low LET protons. Untreated controls and samples exposed to 10 cGy or to 2.5 Gy were analyzed at three different times (4 16 or 24 hours after exposure). Three biological repeats were performed for each condition

Data corresponding to figures contained in manuscript. This dataset is associated with the following publication: Masood, S., E. Pennington, S. Simmons, P. Bromberg, S. Shaikh, R. Rice, A. Gold, Z. Zhang, and J. Samet. Live cell imaging of oxidative stress in human airway epithelial cells exposed to isoprene hydroxyhydroperoxide. Redox Biology. Elsevier B.V., Amsterdam, NETHERLANDS, 51: 102281, (2022).

Human deep space and planetary travel is limited by uncertainties regarding the health risks associated with exposure to galactic cosmic radiation (GCR) and in particular the high linear energy transfer (LET) heavy ion component. Here we assessed the impact of two high-LET ions 56Fe and 28Si and low-LET X rays on genome-wide methylation patterns in human bronchial epithelial cells. We found that all three radiation types induced rapid and stable changes in DNA methylation but at distinct subsets of CpG sites affecting different chromatin compartments. The 56Fe ions induced mostly hypermethylation and primarily affected sites in open chromatin regions including enhancers promoters and edges ( shores ) of CpG islands. The 28Si ion-exposure had mixed effects inducing both hyper and hypomethylation and affecting sites in more repressed heterochromatic environments whereas X rays induced mostly hypomethylation primarily at sites in gene bodies and intergenic regions. Significantly the methylation status of 56Fe ion irradiation sensitive sites but not those affected by X ray or 28Si ions could discriminate tumor from normal tissue for human lung adenocarcinomas and squamous cell carcinomas. Thus high LET radiation exposure leaves a lasting imprint on the epigenome and affects sites relevant to human lung cancer. The 56Fe ion signature may prove useful in monitoring the cumulative biological impact and associated cancer risks encountered by astronauts in deep space. Genome wide DNA methylation profiling of normal human bronchial epithelial cells irradiated with varying doses of 28Si-ion radiation ( 300 MeV/u at 0 0.3 1.0 Gy) 56Fe-ion radiation (600 MeV/u at 0 0.1 0.3 1.0 Gy) or X rays (320 kV at 0 1.0 Gy). Triplicate control and irradiated samples were incubated and sampled at 4 timepoints between 2 and 62 days. The Illumina Infinium 450k Human DNA methylation Beadchip was used to obtain DNA methylation profiles across >485,000 CpGs from collected samples. Samples include: 56Fe ions 4 doses x 4 time points x 3 replicates (4 removed in QC) = 44 samples; 28Si ions = 3 doses x 4 time points x 3 replicates = 36 samples; X ray 2 doses x 4 time points x 3 replicates (2 removed in QC)= 22 samples. Overall design: Bisulphite converted DNA from the 102 samples were hybridized to the Illumina Infinium 450k Human Methylation Beadchip.

The objective of the Rodent Research-6 (RR-6) study was to evaluate muscle atrophy in mice during spaceflight and to test the efficacy of a novel therapeutic to mitigate muscle wasting. The experiment involved an implantable subcutaneous nanochannel delivery system (nDS; between scapula) which delivered the drug formoterol (FMT; a selective Beta-2 adrenoceptor agonist) over the course of time. To this end a cohort of forty 32-weeks-old female C57BL/6NTac mice were either sham operated or implanted with vehicle or treatment-filled nDS launched in two Transporters (20 mice per Transporter) on SpaceX-13 on December 15 2017. They were transferred to Rodent Habitats onboard the International Space Station (ISS) and maintained in microgravity for 29 days (N=20 Live Animal Return [LAR]) or >50 days (N=20 ISS Terminal). After 29 days the 20 LAR animals were returned live to back to Earth on January 13 2018,. After splashdown the animals were ambulatory on-ground for ~4 days until all subjects were processed during one day of dissections. There were two Baseline groups of animals sacrificed (LAR Baseline & FLT Baseline; N=20; 40 animals; ~36 weeks old) at Kennedy Space Center (KSC; 12/9/17). A Ground Control group mimicked the Flight LAR group which was housed at KSC then shipped alive to Novartis Facilities where both the LAR and LAR Ground Control groups were processed (~41 weeks old; 1/16/18). All were anesthetized with isoflurane blood samples were obtained by closed-chest cardiac puncture and the animals were euthanized by exsanguination and thoracotomy. The 20 ISS Terminal mice were anesthetized via intraperitoneal injection of ketamine/xylazine/acepromazine over the course of a four days of dissections (2/6/18 until 2/9/18; 53-56 days after launch; 44 weeks old at time of on-orbit dissections). Blood samples and euthanasia were conducted the same as LAR and Baseline. Following blood draw and hind limb dissection the ISS-terminal animal carcasses were wrapped in aluminum foil placed in a ziploc bag and placed in storage at -80C or colder until return. The ISS-terminal Ground Controls (at KSC) followed the same euthanasia timeline methods and preservation. The final processing of frozen ISS-terminal frozen ISS-terminal Ground Controls and frozen 0-day FLT baseline animals were completed at Houston Methodist Research Institute in Houston TX (5/21/18 until 5/24/18). GeneLab received samples of lung from only sham treated animals (no drug treated animals) from the following groups Flight: LAR (n=10) ISS Terminal (n= 10); Ground Controls: LAR GC (N=9) ISS Terminal GC (N=10) LAR Baseline (n=10) ISS Terminal Baseline (n=9). Total RNA was extracted and sequenced at a target depth of 60 M clusters per sample (ribodepleted paired end 150).

Analysis of human peripheral blood 48 hours after irradiation ex vivo with graded doses of gamma rays. Results have been used in building and testing classifiers to predict exposure dose for use in radiological triage and also provide insight into immune cell responses. Results were compared with those from earlier times and from patients exposed in vivo. Peripheral blood from 5 healthy donors was exposed ex vivo to 0. 0.5 2 5 or 8 Gy gamma-rays and gene expression was analyzed up to 48 hours after exposure.

The existence of a radiation bystander effect in which non-irradiated cells respond to signals from irradiated cells is well established. It raises concerns for the interpretation of risks from exposure to low doses of ionizing radiation. Sparse data exists about the bystander signaling mechanisms and the ability to transmit damaging effects both spatially and temporally. To understand early signaling and cellular changes in bystanders we have measured global gene expression 30 minutes after direct and bystander exposure to alpha particle in primary human lung fibroblasts. Gene ontology and pathway analyses suggested that the earliest measured changes at 30 minutes after treatment are in cell structure motility and adhesion categories and a significant number of genes belong to the category of inflammation and cell-to-cell communication. We investigated time course gene expression profiles of matrix metalloproteinases 1 and 3 (MMP1 and MMP3) chemokine ligands 2 3 and 5 (CXCL2 CXCL3 and CXCL5) interleukins 1a 1b 6 and 33 (IL1A IL1B IL6 and IL33) growth differentiation factor 15 (GDF15) and superoxide dismutase2 (SOD2) by real time quantitative PCR. These encode proteins involved in cellular signaling via the NFkappaB pathway and time course of mRNA levels revealed an increased response at 30 minutes after irradiation followed by another wave at 4 to 6 hours. We also investigated protein modifications in the AKT-GSK-3 signaling pathway and found that in irradiated cells AKT and GSK3beta are hyper-phosphorylated at 30 minutes and this effect is maintained until 4 hours after exposure. In bystanders there is a similar response with a delay of 30 minutes. In irradiated cells inactivated GSK3beta led to decreased phosphorylation of beta-catenin. Our results are the first to show that the radiation induced bystander signal can induce a widespread gene expression response as early as 30 minutes after exposure and that these changes are accompanied by protein modification of signaling modules such as AKT and GSK3beta. There are 12 total samples 4 corresponding biological replicates of IMR90 cells that were not irradiated (control=C) irradiated (alpha=A) and bystander (B) cells were harvested 0.5 hr after treatment