Characteristics of cadmium translocation and isotope fractionation in Ricinus communis seedlings: Effects from split/cut-root and limited nutrients

Studying cadmium (Cd) transport in plants will improve the current understanding of Cd tolerance mechanisms. Due to the influence of analytical techniques, the application of Cd isotopes in plants is still in its early stages. Therefore, the relationships between Cd isotope fractionation and Cd tran...

Full description

Saved in:
Bibliographic Details
Published in:The Science of the total environment 2022-05, Vol.819, p.152493-152493, Article 152493
Main Authors: Wei, Rongfei, Guo, Qingjun, Zhang, Qian, Ma, Jie
Format: Article
Language:English
Subjects:
Cadmium
Cadmium - analysis
Heavy metal
Isotope fractionation
Isotopes
Nutrients
Plant Leaves - chemistry
Plant Roots - metabolism
Ricinus - metabolism
Ricinus communis
Seedlings - metabolism
Soil Pollutants - analysis
Translocation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Studying cadmium (Cd) transport in plants will improve the current understanding of Cd tolerance mechanisms. Due to the influence of analytical techniques, the application of Cd isotopes in plants is still in its early stages. Therefore, the relationships between Cd isotope fractionation and Cd translocation in plants remain unclear. In this study, we cultured Ricinus communis in hydroponic solutions during split/cut-root experiments and limited and infinite nutrient experiments. To understand the Cd transport process, the Cd2+ and other ion concentrations in different tissues (i.e., roots, stems, and leaves) and nutrient solutions, Cd isotope composition and the soluble protein in tissues were measured. The results showed that although significant effects were evident in the top leaves, the principal roots had less pronounced effects on Cd2+ translocation in the stems. Moreover, Cd underwent homolateral transport before it was translocated from the principal roots to the leaves on the side without Cd. It was apparent that the stems were responsible for translocating Cd2+ in plants. In addition, the continuous supply of high Cd2+ concentrations inhibited the growth of the top leaves, while in low Cd2+ concentrations, it was gradually transferred to the top leaves. Moreover, the tissues of R. communis were enriched with lighter Cd isotopes compared with the solutions. The clear differences between the Cd isotope fractionation of leaves under infinite and limited nutrient experiments may be attributed to plant growth and Cd uptake rates. This study provides important information for understanding Cd2+ translocation in R. communis and furthers our understanding of its tolerance and hyperaccumulation. [Display omitted] •Cd underwent homolateral transport before translocation from the principal roots to the leaves on the side without Cd.•Stem appeared to be the site translocating Cd in R. communis.•The continuous supply of Cd inhibited the growth of top leaves while the Cd were gradually transferred to the top leaves during low Cd conditions.•The clear differences between the Cd isotope fractionation of leaves under different experiments may be attributed to plant growth and Cd uptake rates.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2021.152493