Multi-Scale Tolerance Mechanisms of <i>Xanthium strumarium</i> L. Under Lead Stress and Its Application in Phytoremediation

Multi-Scale Tolerance Mechanisms of <i>Xanthium strumarium</i> L. Under Lead Stress and Its Application in Phytoremediation

Heavy metal pollution poses a global environmental challenge, with lead (Pb) being particularly concerning due to its persistence and toxicity. This study investigated <i>Xanthium strumarium</i> L. from China’s Yellow River Sanmenxia section through hydroponic experiments (0–600 mg/L Pb&...

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Bibliographic Details
Main Authors: Shilin Xu, Xiaofang Wang, Zichen Meng, Pingyao Cheng, Wei Li, You Zhou, Yongsheng Li
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Plants
Subjects:
lead pollution
phytoremediation
<i>Xanthium strumarium</i> L.
heavy metal tolerance mechanisms
Online Access:https://www.mdpi.com/2223-7747/14/9/1307
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Summary:Heavy metal pollution poses a global environmental challenge, with lead (Pb) being particularly concerning due to its persistence and toxicity. This study investigated <i>Xanthium strumarium</i> L. from China’s Yellow River Sanmenxia section through hydroponic experiments (0–600 mg/L Pb<sup>2+</sup>, 1–11 d exposure) to elucidate its Pb<sup>2+</sup> response mechanisms. Integrated analyses (EDX, FTIR, thermogravimetry, hyperspectral imaging) revealed a three-phase sequestration strategy: the roots immobilized 88.55% of Pb through pectin carboxyl de-esterification and lignin–Pb complexation, while the stems and leaves retained <11.14% and <0.31%, respectively. A critical threshold (300 mg/L) triggered nonlinear Pb accumulation escalation. Thermogravimetric analysis demonstrated enhanced cell wall stability under Pb stress (66.7% residual carbon increase at 600 mg/L). Hyperspectral features (1670 nm band intensity) effectively tracked physiological stress dynamics. The findings establish <i>X. strumarium</i>’s superior suitability for root-based immobilization rather than phytoextraction in Pb-contaminated sites, with its low translocation efficiency minimizing ecological risks. The identified concentration threshold and spectral biomarkers provide multi-scale insights for optimizing in situ phytostabilization strategies, advancing both theoretical understandings and practical applications in heavy metal remediation.
ISSN:2223-7747

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