Hurem Selma, Martín Leonardo Martín, Brede Dag Anders, Skjerve Eystein, Nourizadeh-Lillabadi Rasoul, Lind Ole Christian, Christensen Terje, Berg Vidar, Teien Hans-Christian, Salbu Brit, Oughton Deborah Helen, Aleström Peter, Lyche Jan Ludvig
Norwegian University of Life Sciences (NMBU), CERAD CoE, Faculty of Veterinary Medicine and Biosciences, Oslo, Norway.
University of Camagüey Ignacio Agramonte y Loynaz (UC), Faculty of Agropecuary Sciences, Camagüey, Cuba.
PLoS One. 2017 Jun 19;12(6):e0179259. doi: 10.1371/journal.pone.0179259. eCollection 2017.
Ionizing radiation from natural sources or anthropogenic activity has the potential to cause oxidative stress or genetic damage in living organisms, through the ionization and excitation of molecules and the subsequent production of free radicals and reactive oxygen species (ROS). The present work focuses on radiation-induced biological effects using the zebrafish (Danio rerio) vertebrate model. Changes in developmental traits and gene expression in zebrafish were assessed after continuous external gamma irradiation (0.4, 3.9, 15 and 38 mGy/h) with corresponding controls, starting at 2.5 hours post fertilization (hpf) and lasting through embryogenesis and the early larval stage. The lowest dose rate corresponded to recommended benchmarks at which adverse effects are not expected to occur in aquatic ecosystems (2-10 mGy/day). The survival observed at 96 hours post fertilization (hpf) in the 38 mGy/h group was significantly lower, while other groups showed no significant difference compared to controls. The total hatching was significantly lower from controls in the 15 mGy/h group and a delay in hatching onset in the 0.4 mGy/h group was observed. The deformity frequency was significantly increased by prolonged exposure duration at dose rates ≥ 0.4 mGy/h. Molecular responses analyzed by RNA-seq at gastrulation (5.5 hpf transcriptome) indicate that the radiation induced adverse effects occurred during the earliest stages of development. A dose-response relationship was found in the numbers of differentially regulated genes in exposure groups compared to controls at a total dose as low as 1.62 mGy. Ingenuity Pathway Analysis identified retinoic acid receptor activation, apoptosis, and glutathione mediated detoxification signaling as the most affected pathways in the lower dose rate (0.54 mGy/h), while eif2 and mTOR, i.e., involved in the modulation of angiogenesis, were most affected in higher dose rates (5.4 and 10.9 mGy/h). By comparing gene expression data, myc was found to be the most significant upstream regulator, followed by tp53, TNF, hnf4a, TGFb1 and cebpa, while crabp2b and vegfab were identified as most frequent downstream target genes. These genes are associated with various developmental processes. The present findings show that continuous gamma irradiation (≥ 0.54 mGy/h) during early gastrula causes gene expression changes that are linked to developmental defects in zebrafish embryos.
来自自然源或人为活动的电离辐射有可能通过分子的电离和激发以及随后自由基和活性氧(ROS)的产生,在生物体中引起氧化应激或基因损伤。本研究使用斑马鱼(Danio rerio)脊椎动物模型聚焦于辐射诱导的生物学效应。在受精后2.5小时(hpf)开始,对斑马鱼进行连续外部伽马辐射(0.4、3.9、15和38 mGy/h)并设置相应对照,持续整个胚胎发育和幼体早期阶段,评估斑马鱼发育特征和基因表达的变化。最低剂量率对应于推荐基准,在该基准下预计在水生生态系统中不会出现不利影响(2 - 10 mGy/天)。在38 mGy/h组中观察到受精后96小时(hpf)的存活率显著降低,而其他组与对照组相比无显著差异。15 mGy/h组的总孵化率显著低于对照组,并且在0.4 mGy/h组中观察到孵化开始延迟。在剂量率≥0.4 mGy/h时,延长暴露持续时间会使畸形频率显著增加。通过RNA测序在原肠胚形成期(5.5 hpf转录组)分析的分子反应表明,辐射诱导的不利影响发生在发育的最早阶段。在总剂量低至1.62 mGy时,与对照组相比,暴露组中差异调节基因的数量呈现剂量 - 反应关系。通路分析确定视黄酸受体激活、凋亡和谷胱甘肽介导的解毒信号通路是较低剂量率(0.54 mGy/h)下受影响最大的通路,而参与血管生成调节的eif2和mTOR在较高剂量率(5.4和10.9 mGy/h)下受影响最大。通过比较基因表达数据,发现myc是最显著的上游调节因子,其次是tp53、TNF、hnf4a、TGFb1和cebpa,而crabp2b和vegfab被确定为最常见的下游靶基因。这些基因与各种发育过程相关。本研究结果表明,在原肠胚早期进行连续伽马辐射(≥0.54 mGy/h)会导致基因表达变化,这些变化与斑马鱼胚胎的发育缺陷有关。
