Improving Lettuce Tolerance to Cadmium Stress: Insights from Raw vs. Cystamine-Modified Biochar

Improving Lettuce Tolerance to Cadmium Stress: Insights from Raw vs. Cystamine-Modified Biochar

Understanding the interactions among biochar, plants, soils, and microbial communities is essential for developing effective and eco-friendly soil remediation strategies. This study investigates the role of cystamine-modified biochar (Cys-BC) in alleviating cadmium (Cd) toxicity in lettuce, comparin...

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Bibliographic Details
Main Authors: Rongqi Chen, Xi Duan, Ruoxuan Xu, Tao Zhao
Format: Article
Language:English
Published: MDPI AG 2024-12-01
Series:Horticulturae
Subjects:
Cd contamination
modified biochar
antioxidant response
soil properties
microbial communities
Online Access:https://www.mdpi.com/2311-7524/10/12/1323
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Summary:Understanding the interactions among biochar, plants, soils, and microbial communities is essential for developing effective and eco-friendly soil remediation strategies. This study investigates the role of cystamine-modified biochar (Cys-BC) in alleviating cadmium (Cd) toxicity in lettuce, comparing its effects to those of raw biochar. Lettuce plants were exposed to Cd stress (1–5 mg kg<sup>−1</sup>), and the effects of Cys-BC were assessed by measuring plant biomass, photosynthetic efficiency, antioxidant activity, Cd bioavailability, and soil microbial diversity. Cys-BC significantly enhanced plant biomass, with increases in above-ground growth (40.54–44.95%) and root biomass (37.54–47.44%) compared to Cd-stressed controls. Photosynthetic parameters improved by up to 91.02% for chlorophyll-a content and 37.93% for the net photosynthetic rate. Cys-BC mitigated oxidative stress, increasing antioxidant activities by 73.83% to 99.39%. Additionally, Cys-BC reduced available Cd levels in the soil, primarily through enhanced cation exchange rather than changes in pH. Plant responses to Cd stress included increased glutathione reductase activity and elevated cysteine levels, which further contributed to Cd passivation. Microbial diversity in the soil increased, particularly among sulfur- and nitrogen-cycling bacteria such as <i>Deltaproteobacteria</i> and <i>Nitrospira</i>, suggesting their role in mitigating Cd stress. These findings highlight the potential of Cys-BC as an effective agent for the remediation of Cd-contaminated soils.
ISSN:2311-7524

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