水培条件下莴苣对铯的吸收和转运

Leiping Shi, Long-miao Yuan, Rui-Yan Li, Wei Wang, Zhe Ding, Jianjun Liang, Junli Qiu, Ping Li
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引用次数: 0

摘要

植物对放射性铯的吸收是评估放射性铯环境风险的关键。然而,RCs在水-蔬菜体系中的迁移过程尚不清楚。采用水培法研究了不同条件下生菜对Cs+ (0 ~ 10 mM)的吸收和积累过程。结果表明,Cs+暴露浓度越高,吸收速率越快,有利于Cs+的吸收和积累。随着Cs+浓度的增加,根和叶对K+的吸收受到显著抑制,而对Ca2+和Mg2+的吸收则不明显。结果表明,K+和Ca2+浓度越高,根系对Cs+吸收的抑制作用越强。Cs+的吸收导致叶绿素含量下降,对植株光合作用产生负面影响,从而对生菜形态产生负面影响,生物量和根长明显减少。高浓度Cs+胁迫后,生菜生长过程中谷胱甘肽(GSH)、丙二醛(MDA)含量和根系活力均增加,对生菜抗氧化系统造成胁迫。叶片中Cs+富集系数在8 ~ 217之间。转移因子在0.114 ~ 0.828之间,说明高Cs+浓度可以促进Cs+从根向叶的转移。本研究提供了更多关于RCs从水到食物链转移的信息,促进了对RCs潜在风险的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Uptake and Translocation of Cesium in Lettuce (Lactuca sativa L.) under Hydroponic Conditions
The uptake of radiocesium (RCs) by plants is key to the assessment of its environmental risk. However, the transfer process of RCs in the water-vegetable system still remains unclear. In this work, the uptake and accumulation processes of Cs+ (0-10 mM) in lettuce were explored under different conditions by using hydroponics. The results showed that the higher exposure concentration of Cs+ could lead to a faster uptake rate and would be beneficial to the uptake and accumulation of Cs+. The uptake of K+ by roots and leaves was inhibited significantly when Cs+ concentration increased, but unapparent for Ca2+ and Mg2+. It was found that the higher K+ and Ca2+ concentration was, the higher inhibition was found for the uptake of Cs+ in root. The uptake of Cs+ leads the decrease of chlorophyll content and brought a negative effect on plant photosynthesis, consequently, a negative effect on lettuce morphology and obvious decrease of biomass and root length. The contents of glutathione (GSH), malondialdehyde (MDA), and root vitality were increasing during the growth following stress of high concentrations of Cs+, which caused stresses on the antioxidant system of lettuce. The enrichment coefficient for Cs+ in leaves was in the range of 8-217. Moreover, the transfer factor was in the range of 0.114-0.828, which suggested that the high Cs+ concentration could enhance the transfer of Cs+ from lettuce root to leaf. This study provides more information on the transfer of RCs from water to food chain, promoting the understanding of the potential risk of RCs.
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