Lesya Zub , Mariana Prokopuk , Igor Goncharenko , Dmitri Gudkov
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In this study, we aim to determine whether long-term radiation exposure has affected organs of reproductive structure (flower, pollen, seed) and, consequently, the viability of local populations of this species. All the traits analysed showed an inverse relationship with the absorbed dose rate of the maternal plants. It was determined that with an increase in the absorbed dose rate, the pollen size decreases, and the range of individual grains in the sample begins to vary more: small, heterogeneous in shape and size pollen grains are formed. Additionally, a decrease in pollen grain size correlates with a decrease in the proportion of fertile pollen. Pollen grains viability (fertility) decreases by 20–40% with increasing radiation dose rate. The response of reproductive structures to radiation exposure is non-linear: already at low doses (>2 μGy/h), negative changes in functional and morphological traits are observed, while at higher doses (9–13 μGy/h), the changes slow down. 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引用次数: 0
摘要
在切尔诺贝利事故的急性期,污染区的生物群受到了高剂量的电离辐射。虽然这些剂量随着时间的推移大大降低,但辐照仍持续了很长时间。这种长期辐照可被视为导致生物基因改变的直接原因,因此,寻找放射性污染影响下生物群状态的相关变化是一项极为紧迫的任务。水生大型藻类 Glyceria maxima 是切尔诺贝利禁区洪泛区水体沿岸植被中最常见的共生植物,能够大量聚集放射性核素。在这项研究中,我们旨在确定长期辐照是否会影响生殖结构器官(花、花粉、种子),进而影响该物种当地种群的生存能力。所分析的所有性状都与母本植物的吸收剂量率呈反比关系。据测定,随着吸收剂量率的增加,花粉的大小会减小,样本中单个花粉粒的范围也开始变得更大:形成的花粉粒会更小、形状和大小更不均匀。此外,花粉粒尺寸的减小与可育花粉比例的减小有关。随着辐射剂量率的增加,花粉粒的活力(可育性)会降低 20-40%。生殖结构对辐照的反应是非线性的:低剂量(2 μGy/h)时,功能和形态特征就会出现负面变化,而高剂量(9-13 μGy/h)时,变化则会减缓。据推测,辐照主要影响早期生殖阶段(花粉粒和部分花朵),而决定水库营养状况的水中主要营养物质则影响后期生殖阶段(种子)。
The effects of long-term radiation exposure on the reproductive structures of Glyceria maxima (Hartm.) Holmb.: A case study in the Chornobyl exclusion zone
During the acute phase of the Chornobyl accident the biota of the contaminated area was exposed to high doses of ionising radiation. Although these doses decreased significantly over the years, the exposure persisted over a prolonged period. This long-term exposure can be considered as a direct cause of genetic modifications occurring in organisms, and the search for correlative changes in the state of biota under the impact of radioactive contamination is an extremely urgent task. The aquatic macrophyte Glyceria maxima is the most common coenosis-forming plant of the littoral vegetation of the floodplain water bodies in the Chornobyl Exclusion Zone, and is capable of concentrating radionuclides in significant quantities. In this study, we aim to determine whether long-term radiation exposure has affected organs of reproductive structure (flower, pollen, seed) and, consequently, the viability of local populations of this species. All the traits analysed showed an inverse relationship with the absorbed dose rate of the maternal plants. It was determined that with an increase in the absorbed dose rate, the pollen size decreases, and the range of individual grains in the sample begins to vary more: small, heterogeneous in shape and size pollen grains are formed. Additionally, a decrease in pollen grain size correlates with a decrease in the proportion of fertile pollen. Pollen grains viability (fertility) decreases by 20–40% with increasing radiation dose rate. The response of reproductive structures to radiation exposure is non-linear: already at low doses (>2 μGy/h), negative changes in functional and morphological traits are observed, while at higher doses (9–13 μGy/h), the changes slow down. It is assumed that the radiation exposure mainly affects the early reproductive stages (pollen grains and partially flowers), while the main nutrients in water, that determine the trophic status of the reservoir, affects the late stages (seeds).
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