补充胆碱可减少茄果类植物幼苗对镉的吸收并减轻镉的毒性。

IF 5.4 3区 材料科学 Q2 CHEMISTRY, PHYSICAL
Ayşegül Akpinar, Asuman Cansev
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引用次数: 0

摘要

要在受重金属污染的土壤中实现植物的可持续生产,就必须制定新的战略,以造福于人类和其他生物。镉(Cd)是植物常见的重金属污染物,目前关于使用外源生物调节剂来减少镉污染在植物体内的积累和毒性影响的信息还很有限。胆碱是一种内源性叔胺,已知可提高植物的抗逆性,但其在某些条件下的作用机制尚待确定。本研究调查了叶面补充胆碱(10 mM)对暴露于镉施用量(土壤中 50 mg/L)的茄科植物幼苗的影响。秧苗被随机分为五组:对照组(E1)、镉胁迫组(E2)、镉胁迫后补充胆碱组(E3)、胆碱组(E4)和镉胁迫前补充胆碱组(E5)。施药后,分析了镉含量、生长发育参数(叶绿素含量、鲜重和干重)、氧化应激参数(H2O2 和 MDA 含量)以及抗氧化防御系统(SOD、GSH、ASA 和 TPC 含量)。与镉胁迫组相比,镉胁迫后补充胆碱可使根中增加的镉含量降低 38%,但不会改变叶片中增加的镉含量(p > 0.05)。镉胁迫前补充胆碱可使根中的镉含量降低 87.5%,叶片中的镉含量降低 50%。在镉胁迫后和镉胁迫前补充胆碱可增加根和叶的鲜重和干重。虽然镉组(E2)的 H2O2 水平和 SOD 活性都有所提高,但所有胆碱补充剂(E3、E4、E5)的 H2O2 水平都没有明显变化。因此,在镉胁迫前补充胆碱(E5)未观察到脂质过氧化(MDA),但在镉胁迫后补充胆碱(E3),MDA 含量比镉胁迫组(E2)减少了 40%。与对照组(E1)相比,镉胁迫后和镉胁迫前(E3、E5)补充胆碱可使 AsA 含量增加 30%,而镉胁迫组(E2)则减少 60%。此外,在镉胁迫(E5)前补充胆碱可使 TPC 增加 33%,而镉胁迫组(E2)则减少 18%,此外,在镉胁迫(E3)后补充胆碱时,与对照组相比未观察到任何变化。这些数据表明,胆碱可以通过减少镉的吸收来防止镉毒性对植物生长的抑制。本研究提供的结果可能会提高重金属污染地区作物生产的质量和效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Choline supplementation reduces cadmium uptake and alleviates cadmium toxicity in Solanum lycopersicum seedlings.

Sustainable plant production in soil polluted with heavy metals requires that novel strategies are developed for the benefit of humans and other living things. Cadmium (Cd) is a common heavy metal pollutant for plants, and there is limited information on the use of exogenous bio-regulators to reduce the accumulation and toxic effects of Cd pollution in plants. Choline is an endogenous quertarnary amine that is known to improve stress tolerance in plants, while its mechanism of action in certain conditions is yet to be determined. This study investigated the effects of foliar choline supplementation (10 mM) on Solanum lycopersicum seedlings exposed to Cd application (50 mg/L in soil). The seedlings were randomized to five groups: Control (E1), Cd stress (E2), Choline supplementation after Cd stress (E3), Choline (E4), and Choline supplementation before Cd stress (E5). Following the applications, the Cd content, growth and development parameters (chlorophyll content, fresh and dry weight), oxidative stress parameters (H2O2 and MDA contents), as well as antioxidative defense system (SOD, GSH, AsA, and TPC contents) were analyzed. Choline supplementation after Cd stress reduced the enhanced Cd content in roots by 38% but did not alter it in leaves (p > 0.05) compared to the Cd group. Choline supplementation before Cd stress decreased Cd content both in roots by 87.5% and in leaves by 50%. Choline supplementation after and before Cd stress increased fresh and dry weights in both roots and leaves. While the Cd group (E2) increased the H2O2 level and SOD activity, no remarkable change was observed in H2O2 levels in all choline supplementations (E3, E4, E5). Therefore, lipid peroxidation (MDA) was not observed in choline supplementation before Cd stress (E5), however, when the choline was applied after Cd stress (E3) MDA content was reduced by 40% compared with the Cd stress group (E2). Choline supplementations after and before Cd stress (E3, E5) increased AsA content by 30%, while the Cd group (E2) decreased it by 60% compared with the control group (E1). Choline supplementations before Cd stress (E5) increased TPC by 33%, while the Cd group (E2) decreased it by 18%, moreover, when choline was applied after Cd stress (E3), no change was observed compared to the control group. These data suggest that choline prevents inhibition of plant growth due to Cd toxicity by reducing Cd uptake. The results provided in the present study are likely to enhance the quality and efficiency of crop production in heavy metal-polluted areas.

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来源期刊
ACS Applied Energy Materials
ACS Applied Energy Materials Materials Science-Materials Chemistry
CiteScore
10.30
自引率
6.20%
发文量
1368
期刊介绍: ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.
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