The roles of organic amendments and plant treatments in soil polychlorinated biphenyl dissipation under oxic and sequential anoxic–oxic conditions

Understanding polychlorinated biphenyl (PCB) degradation in sequential anaerobic−aerobic remediation is crucial for effective remediation strategies. In this study, microcosm and greenhouse experiments were conducted to dissect the effects of organic amendments (carbon-based) and plant treatments (r...

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Published in:Environmental research 2024-12, Vol.262 (Pt 2), p.119943, Article 119943
Main Authors: Yan, Meng, Peng, Tingting, Zhao, Ling, Li, Qigang, Wu, Ruini, Wang, Yiming, Wu, Yucheng, Teng, Ying, Xiang, Xingjia, Zeng, Jun, Lin, Xiangui
Format: Article
Language:English
Subjects:
Anaerobiosis
Anoxic–oxic conditions
Biodegradation, Environmental
Bioremediation
Lolium - growth & development
Lolium - metabolism
Microbial community
Organic amendment
Polychlorinated biphenyls
Polychlorinated Biphenyls - metabolism
Sequential treatment
Soil - chemistry
Soil Microbiology
Soil Pollutants - metabolism
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Summary:Understanding polychlorinated biphenyl (PCB) degradation in sequential anaerobic−aerobic remediation is crucial for effective remediation strategies. In this study, microcosm and greenhouse experiments were conducted to dissect the effects of organic amendments (carbon-based) and plant treatments (ryegrass) on soil PCB dissipation under oxic and sequential anoxic–oxic conditions. We analyzed the soil bacterial community in greenhouse experiments using high-throughput sequencing to explore plant-pollutant-microbe interactions. Microcosm results showed that organic amendments alone did not facilitate aerobic PCB removal, but significantly accelerated PCB dechlorination under anoxic conditions altering the profiles of PCB congeners. In standard greenhouses, plant treatments substantially increased PCB dissipation to 50.8 ± 3.9%, while organic amendments aided phytoremediation by promoting plant growth, increasing PCB removal to 65.9 ± 3.2%. In sequential anaerobic–aerobic greenhouses, plant growth was inhibited by flooding treatment while flooding stress was markedly alleviated by organic amendments. Plant treatments alone during sequential treatments did not lead to PCB dissipation; however, dissipation was significantly promoted following organic amendments, achieving a removal of 41.2 ± 5.7%. This PCB removal was primarily due to anaerobic dechlorination during flooding (27.8 ± 0.5% removal), rather than from plant growth stimulation in subsequent planting phase. Co-occurrence network and functional prediction analyses revealed that organic amendments recruited specific bacterial clusters with distinct functions under different conditions, especially stimulating plant-microbe interactions and xenobiotics biodegradation pathways in planted systems. The findings provide valuable guidance for the design of practical remediation strategies under various remedy scenarios, such as in arable or paddy fields. [Display omitted] •Plant treatments enhance PCB dissipation in standard greenhouses.•Organic amendments aid phytoremediation in standard greenhouses.•Sequential anoxic-oxic greenhouses do not favor phytoremediation.•Organic amendments stimulate PCB dechlorination and plant-microbe interactions. Synopsis: This study revealed different roles of organic amendments in promoting soil PCB transformation under oxic and sequential anoxic–oxic conditions.
ISSN:0013-9351
1096-0953
1096-0953
DOI:10.1016/j.envres.2024.119943