Abstract
Fish have been highly exposed to radiation in freshwater systems after the Chernobyl Nuclear Power Plant (NPP) accident in 1986 and in freshwater and marine systems after the more recent Fukushima NPP accident in 2011. In the years after the accident, the radioactivity levels rapidly declined due to radioactive decay and environmental processes, but chronic lower dose exposures persisted. To gain insights into the long-term effects of environmental low dose radiation on fish ovaries development, a high-throughput transcriptomic approach including a de novo assembly was applied to different gonad phenotypes of female perch: developed gonads from reference lakes, developed/irradiated from medium contaminated lake, and both developed/irradiated and undeveloped from more highly contaminated lakes. This is the most comprehensive analysis to date of the gene responses in wildlife reproductive system to radiation. Some gene responses that were modulated in irradiated gonads were found to be involved in biological processes including cell differentiation and proliferation (ggnb2, mod5, rergl), cytoskeleton organization (k1C18, mtpn), gonad development (nell2, tcp4), lipid metabolism (ldah, at11b, nltp), reproduction (cyb5, cyp17A, ovos), DNA damage repair (wdhd1, rad51, hus1), and epigenetic mechanisms (dmap1). Identification of these genes provides a better understanding of the underlying molecular mechanisms underpinning the development of the gonad phenotypes of wild perch and how fish may respond to chronic exposure to radiation in their natural environment, though causal attribution of gene responses remains unclear in the undeveloped gonads.
Highlights
While the biological effects of acute exposure to radiation in laboratory settings is well documented (Frederica radiation database: www.frederica-online.org), little is known about the long-term effects of low dose exposure to radiation on organisms in their natural environment
Histological analyses showed that the undeveloped gonads were composed of immature oocytes only, and that developed gonads, from both reference and irradiated lakes, of both immature and maturing oocytes
Long-term exposure to stress can inhibit gonad development in fish and explain the presence of undeveloped phenotypes, but causal factors are rarely described in the literature
Summary
While the biological effects of acute exposure to radiation in laboratory settings is well documented (Frederica radiation database: www.frederica-online.org), little is known about the long-term effects of low dose exposure to radiation on organisms in their natural environment. The highest dose rate to fish after the Chernobyl accident was estimated to be 400 μGy/h.14. Three decades after the Chernobyl Nuclear Power Plant (NPP) accident, the main radionuclides of concern are 90Sr (a β-emitter) and 137Cs (a β- and γemitter) due to their long radioactive half-lives (28 and 30 years, respectively).[4] The contribution of transuranium radioelements to the total dose to fish at Chernobyl is very low.[4] The total dose to perch (Perca fluviatilis) and roach ( Rutilus rutilus) in 2015 varied from 0.8 to 14.1 and 1.7 to 15.7 μGy/h, respectively.[4] Biomagnification of 137Cs was observed between roach (an omnivorous species) and perch (a carnivorous species) from several lakes in Belarus and Ukraine, 30 years after the Chernobyl NPP accident.[4]
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