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. 2017 Oct;58(8):560-569.
doi: 10.1002/em.22121. Epub 2017 Aug 30.

Genotoxic effects of high dose rate X-ray and low dose rate gamma radiation in ApcMin/+ mice

Anne Graupner  1   2 Dag M Eide  2   3 Dag A Brede  2   4 Michele Ellender  5 Elisabeth Lindbo Hansen  2   6 Deborah H Oughton  2   4 Simon D Bouffler  5 Gunnar Brunborg  1   2 Ann Karin Olsen  1   2
Affiliations

Genotoxic effects of high dose rate X-ray and low dose rate gamma radiation in ApcMin/+ mice

Anne Graupner et al. Environ Mol Mutagen. 2017 Oct.

Abstract

Risk estimates for radiation-induced cancer in humans are based on epidemiological data largely drawn from the Japanese atomic bomb survivor studies, which received an acute high dose rate (HDR) ionising radiation. Limited knowledge exists about the effects of chronic low dose rate (LDR) exposure, particularly with respect to the application of the dose and dose rate effectiveness factor. As part of a study to investigate the development of colon cancer following chronic LDR vs. acute HDR radiation, this study presents the results of genotoxic effects in blood of exposed mice. CBAB6 F1 Apc+/+ (wild type) and ApcMin/+ mice were chronically exposed to estimated whole body absorbed doses of 1.7 or 3.2 Gy 60 Co-γ-rays at a LDR (2.2 mGy h-1 ) or acutely exposed to 2.6 Gy HDR X-rays (1.3 Gy min-1 ). Genotoxic endpoints assessed in blood included chromosomal damage (flow cytometry based micronuclei (MN) assay), mutation analyses (Pig-a gene mutation assay), and levels of DNA lesions (Comet assay, single-strand breaks (ssb), alkali labile sites (als), oxidized DNA bases). Ionising radiation (ca. 3 Gy) induced genotoxic effects dependent on the dose rate. Chromosomal aberrations (MN assay) increased 3- and 10-fold after chronic LDR and acute HDR, respectively. Phenotypic mutation frequencies as well as DNA lesions (ssb/als) were modulated after acute HDR but not after chronic LDR. The ApcMin/+ genotype did not influence the outcome in any of the investigated endpoints. The results herein will add to the scant data available on genotoxic effects following chronic LDR of ionising radiation. Environ. Mol. Mutagen. 58:560-569, 2017. © 2017 The Authors Environmental and Molecular Mutagenesis published by Wiley Periodicals, Inc. on behalf of Environmental Mutagen Society.

Keywords: DNA lesions; blood cells; chronic and acute irradiation; micronuclei; mutation.

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Figures

Figure 1
Figure 1
Overview
Figure 2
Figure 2
Micronuclei assay. Mice were either chronically exposed to gamma‐rays [2.2 mGy h−1, receiving a total absorbed body dose of 1.7 and 3.2 Gy (group I) or only 1.7 Gy (group II)] or acutely irradiated with X rays (1.3 Gy min−1, receiving a total absorbed body dose of 2.6 Gy (group III)); cf. Table I. Each data point represents one mouse: red open circles for CBAB6 F1 Apc+/+ (i.e., wild type) and blue open boxes for ApcMin/+. The percentage of (A) micronucleated blood reticulocytes (% MN‐RET), (B) micronucleated normochromic erythrocytes (% MN‐NCE) and (C) relative reticulocyte population (% RET) are displayed. Same letters indicate that there is no significant difference between groups (P > 0.05); separate analysis for chronic and acute exposure.
Figure 3
Figure 3
Pig‐a gene mutation assay. Refer to legend in Figure 2. Mutant phenotype frequencies of reticulocytes (RETCD24−, (A) and red blood cells (RBCCD24−, (B) and the relative reticulocyte population (% RET, C). Similar letters indicate that there is no significant difference between groups (P > 0.05); separate analysis for chronic and acute exposure.
Figure 4
Figure 4
Single cell gel electrophoresis. Refer to legend in Figure 2. (A) Single strand breaks/alkali labile sites (ssb/als); (B) ssb/als and additional oxidised DNA lesions (assessed by Fpg); (C) Fpg‐sensitive sites (i.e., oxidised DNA lesions only) are displayed. Similar letters indicate that there is no significant difference between groups (P > 0.05); separate analysis for chronic and acute exposure.
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