AI Article Synopsis
- The study investigates how EDDS and gibberellic acid (GA) impact the absorption of copper (Cu) and zinc (Zn) by the grass species Lolium perenne, highlighting differing effects on root and shoot metal accumulation.
- EDDS enhances Cu uptake, leading to more root damage over time, while GA reduces metal absorption and cellular harm, even though it increases plant transpiration.
- Results indicate that EDDS is effective for phytoextraction of Cu and Zn, while GA helps mitigate stress and damage in plants.
Article Abstract
The present study explores the effect of ethylene diamine disuccinic acid (EDDS) and gibberellic acid (GA) application on the phytoextraction of copper and zinc ions by Lolium perenne. When Cu was individually applied, accumulation diminished over time with little translocation from roots to shoots. In contrast, Zn accumulation and damage to roots rapidly increased over 3 days with increase in Zn translocation to shoots. Co-application of Zn to Cu amended treatments enhanced Cu concentration in shoots. For the Cu application, EDDS significantly increased Cu accumulation and the damage to root increased over time, while gibberellic acid applied with Cu and Zn generally lowered metal uptake and decreased cell membrane damage. The application of EDDS and GA-EDDS, by themselves or with Cu and Zn, lowered transpiration and increased translocation, while GA increased transpiration but decreased translocation. EDDS application typically increased metal ion uptake by causing more cell damage, while GA typically lowered the damage and decreased metal uptake even though the transpiration increased over time and plant growth occurred. Furthermore, the behaviour of metal uptake changed over time and, for some treatments, the short-term and long-term response differed greatly. These results show that EDDS can be successfully used in phytoextraction of both Cu and Zn ions by Lolium perenne while GA can resist damage and protect against plant stress.
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| http://dx.doi.org/10.1016/j.chemosphere.2020.127541 | DOI Listing |
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