Contributions of ryegrass, lignin and rhamnolipid to polycyclic aromatic hydrocarbon dissipation in an arable soil
Contributions of ryegrass, lignin and rhamnolipid to polycyclic aromatic hydrocarbon dissipation in an arable soil
Bioremediation of polycyclic aromatic hydrocarbon (PAH)-contaminated soil is often limited by inadequate microbial activity and/or low PAH bioavailability. A pot experiment was performed with an aged contaminated arable soil to explore the remediation potential of ryegrass and lignin, which are believed to improve microbial degradation, as well as the biosurfactant rhamnolipid. On average, the concentration of 15 priority PAHs was reduced by 41.7% in the combined ryegrass, lignin and rhamnolipid treatment after 90 days. In contrast, there was no reduction in PAH concentration when each treatment was used alone. The rhamnolipid was beneficial for successful remediation, as shown by the lack of PAH transformation in all non-rhamnolipid treatments. The total amount of PAHs that accumulated in ryegrass biomass was less than 0.1% of the initial amount in the pot. When the theoretical estimate of plant uptake was considered, it suggested that rhizoremediation rather than direct uptake contributed to PAH dissipation. High-throughput sequencing analysis demonstrated that lignin addition substantially changed the fungal and bacterial communities; however, there was no indication that lignin selected for known bacterial PAH degraders. Nevertheless, a [14C]benz(a)anthracene-spiked microcosm experiment showed that lignin amendment led to enhanced PAH mineralization and nonextractable residue formation. Taken together, these findings highlight the importance of selecting bioremediation treatments that can simultaneously stimulate microbial activity and increase PAH bioavailability to achieve remediation effectively. Treatments incorporating rhizoremediation, biostimulation and biosurfactant addition hold promise for detoxifying aged PAH-contaminated agricultural soil.
Polycyclic aromatic hydrocarbon, Biostimulation, Rhizoremediation, Biosurfactant, Mineralization, Microbial community
27-34
Wu, Yucheng
9836ef79-9643-402b-87b3-cbac3d31c7c5
Ding, Qingmin
0ce8ddc9-68cc-41f8-bf90-30926af31e69
Zhu, Qinghe
9b621c88-6af2-4674-a253-8f1b12fbb643
Zeng, Jun
5a3e9a6a-b815-4712-91fa-8d571cf21f0f
Ji, Rong
6c628191-4c61-4d41-abf7-371ef2eab744
Dumont, Marc
afd9f08f-bdbb-4cee-b792-1a7f000ee511
Lin, Xiangui
e85ce20a-7d62-4747-93d4-6a00cd07f16f
March 2018
Wu, Yucheng
9836ef79-9643-402b-87b3-cbac3d31c7c5
Ding, Qingmin
0ce8ddc9-68cc-41f8-bf90-30926af31e69
Zhu, Qinghe
9b621c88-6af2-4674-a253-8f1b12fbb643
Zeng, Jun
5a3e9a6a-b815-4712-91fa-8d571cf21f0f
Ji, Rong
6c628191-4c61-4d41-abf7-371ef2eab744
Dumont, Marc
afd9f08f-bdbb-4cee-b792-1a7f000ee511
Lin, Xiangui
e85ce20a-7d62-4747-93d4-6a00cd07f16f
Wu, Yucheng, Ding, Qingmin, Zhu, Qinghe, Zeng, Jun, Ji, Rong, Dumont, Marc and Lin, Xiangui
(2018)
Contributions of ryegrass, lignin and rhamnolipid to polycyclic aromatic hydrocarbon dissipation in an arable soil.
Soil Biology and Biochemistry, 118, .
(doi:10.1016/j.soilbio.2017.11.022).
Abstract
Bioremediation of polycyclic aromatic hydrocarbon (PAH)-contaminated soil is often limited by inadequate microbial activity and/or low PAH bioavailability. A pot experiment was performed with an aged contaminated arable soil to explore the remediation potential of ryegrass and lignin, which are believed to improve microbial degradation, as well as the biosurfactant rhamnolipid. On average, the concentration of 15 priority PAHs was reduced by 41.7% in the combined ryegrass, lignin and rhamnolipid treatment after 90 days. In contrast, there was no reduction in PAH concentration when each treatment was used alone. The rhamnolipid was beneficial for successful remediation, as shown by the lack of PAH transformation in all non-rhamnolipid treatments. The total amount of PAHs that accumulated in ryegrass biomass was less than 0.1% of the initial amount in the pot. When the theoretical estimate of plant uptake was considered, it suggested that rhizoremediation rather than direct uptake contributed to PAH dissipation. High-throughput sequencing analysis demonstrated that lignin addition substantially changed the fungal and bacterial communities; however, there was no indication that lignin selected for known bacterial PAH degraders. Nevertheless, a [14C]benz(a)anthracene-spiked microcosm experiment showed that lignin amendment led to enhanced PAH mineralization and nonextractable residue formation. Taken together, these findings highlight the importance of selecting bioremediation treatments that can simultaneously stimulate microbial activity and increase PAH bioavailability to achieve remediation effectively. Treatments incorporating rhizoremediation, biostimulation and biosurfactant addition hold promise for detoxifying aged PAH-contaminated agricultural soil.
Text
Wu et al accepted version
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More information
Accepted/In Press date: 28 November 2017
e-pub ahead of print date: 22 December 2017
Published date: March 2018
Keywords:
Polycyclic aromatic hydrocarbon, Biostimulation, Rhizoremediation, Biosurfactant, Mineralization, Microbial community
Identifiers
Local EPrints ID: 416218
URI: http://eprints.soton.ac.uk/id/eprint/416218
ISSN: 0038-0717
PURE UUID: ba3fe0f3-e557-47a9-8190-b17f57c1023b
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Date deposited: 08 Dec 2017 17:30
Last modified: 16 Mar 2024 06:01
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Contributors
Author:
Yucheng Wu
Author:
Qingmin Ding
Author:
Qinghe Zhu
Author:
Jun Zeng
Author:
Rong Ji
Author:
Xiangui Lin
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