Characteristics of nitrogen distribution and its response to microecosystem changes in green infrastructure with different woody plants

Bei Zhang; Liang Chen; Qizhong Guo; Zhaoxin Zhang; Jijian Lian

doi:10.1016/j.chemosphere.2022.137371

Characteristics of nitrogen distribution and its response to microecosystem changes in green infrastructure with different woody plants

Bei Zhang, Liang Chen, Qizhong Guo, Zhaoxin Zhang, Jijian Lian

Research output: Contribution to journal › Article › peer-review

Abstract

With the acceleration of urbanization, N pollution in rainfall runoff has become the primary cause of eutrophication. In order to control N pollution in rainfall runoff, green infrastructure (GI) has been widely implemented. However, little is known about the process through which plants, especially woody plants, affect N distribution and the microecosystem in GI. Limited information suggests that woody plants mainly affect N distribution and alter the microecosystem through the influence of their roots. Therefore, laboratory tests were conducted to investigate the roles of the taproot plant Sophora japonica and the fibrous root plant Malus baccata and the resultant changes at the microecosystem level regarding N removal in a column-scale GI. After one year of growth, analysis of the morphological traits of the roots revealed that the average root length and diameter of S. japonica were approximately 2.3 and 1.8 times greater than those of M. baccata, respectively. An investigation of microbial diversity revealed that in comparison to the control GI system without plants, the GI systems with S. japonica and M. baccata hosted 45.68% and 59.88% more Actinobacteria, respectively. Further, the soil urease (S-UE) activities in the GI systems with S. japonica and M. baccata were 13.6% and 98.8% higher than that in the control, respectively, and the soil acid protease (S-ALPT) activities were 20.5% and 25.4% higher than that in the control, respectively. Compared to the control and the S. japonica GI system, the NH₃–N content in the soil of the M. baccata GI was 94.4% and 15.2% lower, respectively, and the NO₃–N content was 57.3% and 12.7% lower, respectively. The M. baccata GI system had the lowest NH₃–N and NO₃–N contents because it was most abundant in Actinobacteria and Arthrobacter and had the highest S-UE and S-ALPT activities. The results may be useful for improving N removal in GI containing different woody plants, and by extension for improving control of N pollution from rainfall runoff.

Original language	English (US)
Article number	137371
Journal	Chemosphere
Volume	313
DOIs	https://doi.org/10.1016/j.chemosphere.2022.137371
State	Published - Feb 2023
Externally published	Yes

All Science Journal Classification (ASJC) codes

Environmental Engineering
Environmental Chemistry
Chemistry(all)
Pollution
Public Health, Environmental and Occupational Health
Health, Toxicology and Mutagenesis

Keywords

Ammonia
Enzyme
Microorganism
Nitrate
Rainwater
Roots

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10.1016/j.chemosphere.2022.137371

Cite this

@article{d90dcda2fe984982968df610436e5a5a,

title = "Characteristics of nitrogen distribution and its response to microecosystem changes in green infrastructure with different woody plants",

abstract = "With the acceleration of urbanization, N pollution in rainfall runoff has become the primary cause of eutrophication. In order to control N pollution in rainfall runoff, green infrastructure (GI) has been widely implemented. However, little is known about the process through which plants, especially woody plants, affect N distribution and the microecosystem in GI. Limited information suggests that woody plants mainly affect N distribution and alter the microecosystem through the influence of their roots. Therefore, laboratory tests were conducted to investigate the roles of the taproot plant Sophora japonica and the fibrous root plant Malus baccata and the resultant changes at the microecosystem level regarding N removal in a column-scale GI. After one year of growth, analysis of the morphological traits of the roots revealed that the average root length and diameter of S. japonica were approximately 2.3 and 1.8 times greater than those of M. baccata, respectively. An investigation of microbial diversity revealed that in comparison to the control GI system without plants, the GI systems with S. japonica and M. baccata hosted 45.68% and 59.88% more Actinobacteria, respectively. Further, the soil urease (S-UE) activities in the GI systems with S. japonica and M. baccata were 13.6% and 98.8% higher than that in the control, respectively, and the soil acid protease (S-ALPT) activities were 20.5% and 25.4% higher than that in the control, respectively. Compared to the control and the S. japonica GI system, the NH3–N content in the soil of the M. baccata GI was 94.4% and 15.2% lower, respectively, and the NO3–N content was 57.3% and 12.7% lower, respectively. The M. baccata GI system had the lowest NH3–N and NO3–N contents because it was most abundant in Actinobacteria and Arthrobacter and had the highest S-UE and S-ALPT activities. The results may be useful for improving N removal in GI containing different woody plants, and by extension for improving control of N pollution from rainfall runoff.",

keywords = "Ammonia, Enzyme, Microorganism, Nitrate, Rainwater, Roots",

author = "Bei Zhang and Liang Chen and Qizhong Guo and Zhaoxin Zhang and Jijian Lian",

note = "Funding Information: This work was supported by the National Natural Science Foundation of China (No. 42277046 and No. U20A20316 ), and the Special Project for Upgrading Technology-Based Small and Medium-Sized Enterprises from Sino-Singapore Tianjin Eco-City-Study on rainwater storage and utilization in coastal saline alkali areas. Publisher Copyright: {\textcopyright} 2022",

year = "2023",

month = feb,

doi = "10.1016/j.chemosphere.2022.137371",

language = "English (US)",

volume = "313",

journal = "Chemosphere",

issn = "0045-6535",

publisher = "Elsevier Limited",

}

TY - JOUR

T1 - Characteristics of nitrogen distribution and its response to microecosystem changes in green infrastructure with different woody plants

AU - Zhang, Bei

AU - Chen, Liang

AU - Guo, Qizhong

AU - Zhang, Zhaoxin

AU - Lian, Jijian

N1 - Funding Information: This work was supported by the National Natural Science Foundation of China (No. 42277046 and No. U20A20316 ), and the Special Project for Upgrading Technology-Based Small and Medium-Sized Enterprises from Sino-Singapore Tianjin Eco-City-Study on rainwater storage and utilization in coastal saline alkali areas. Publisher Copyright: © 2022

PY - 2023/2

Y1 - 2023/2

N2 - With the acceleration of urbanization, N pollution in rainfall runoff has become the primary cause of eutrophication. In order to control N pollution in rainfall runoff, green infrastructure (GI) has been widely implemented. However, little is known about the process through which plants, especially woody plants, affect N distribution and the microecosystem in GI. Limited information suggests that woody plants mainly affect N distribution and alter the microecosystem through the influence of their roots. Therefore, laboratory tests were conducted to investigate the roles of the taproot plant Sophora japonica and the fibrous root plant Malus baccata and the resultant changes at the microecosystem level regarding N removal in a column-scale GI. After one year of growth, analysis of the morphological traits of the roots revealed that the average root length and diameter of S. japonica were approximately 2.3 and 1.8 times greater than those of M. baccata, respectively. An investigation of microbial diversity revealed that in comparison to the control GI system without plants, the GI systems with S. japonica and M. baccata hosted 45.68% and 59.88% more Actinobacteria, respectively. Further, the soil urease (S-UE) activities in the GI systems with S. japonica and M. baccata were 13.6% and 98.8% higher than that in the control, respectively, and the soil acid protease (S-ALPT) activities were 20.5% and 25.4% higher than that in the control, respectively. Compared to the control and the S. japonica GI system, the NH3–N content in the soil of the M. baccata GI was 94.4% and 15.2% lower, respectively, and the NO3–N content was 57.3% and 12.7% lower, respectively. The M. baccata GI system had the lowest NH3–N and NO3–N contents because it was most abundant in Actinobacteria and Arthrobacter and had the highest S-UE and S-ALPT activities. The results may be useful for improving N removal in GI containing different woody plants, and by extension for improving control of N pollution from rainfall runoff.

AB - With the acceleration of urbanization, N pollution in rainfall runoff has become the primary cause of eutrophication. In order to control N pollution in rainfall runoff, green infrastructure (GI) has been widely implemented. However, little is known about the process through which plants, especially woody plants, affect N distribution and the microecosystem in GI. Limited information suggests that woody plants mainly affect N distribution and alter the microecosystem through the influence of their roots. Therefore, laboratory tests were conducted to investigate the roles of the taproot plant Sophora japonica and the fibrous root plant Malus baccata and the resultant changes at the microecosystem level regarding N removal in a column-scale GI. After one year of growth, analysis of the morphological traits of the roots revealed that the average root length and diameter of S. japonica were approximately 2.3 and 1.8 times greater than those of M. baccata, respectively. An investigation of microbial diversity revealed that in comparison to the control GI system without plants, the GI systems with S. japonica and M. baccata hosted 45.68% and 59.88% more Actinobacteria, respectively. Further, the soil urease (S-UE) activities in the GI systems with S. japonica and M. baccata were 13.6% and 98.8% higher than that in the control, respectively, and the soil acid protease (S-ALPT) activities were 20.5% and 25.4% higher than that in the control, respectively. Compared to the control and the S. japonica GI system, the NH3–N content in the soil of the M. baccata GI was 94.4% and 15.2% lower, respectively, and the NO3–N content was 57.3% and 12.7% lower, respectively. The M. baccata GI system had the lowest NH3–N and NO3–N contents because it was most abundant in Actinobacteria and Arthrobacter and had the highest S-UE and S-ALPT activities. The results may be useful for improving N removal in GI containing different woody plants, and by extension for improving control of N pollution from rainfall runoff.

KW - Ammonia

KW - Enzyme

KW - Microorganism

KW - Nitrate

KW - Rainwater

KW - Roots

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U2 - 10.1016/j.chemosphere.2022.137371

DO - 10.1016/j.chemosphere.2022.137371

M3 - Article

C2 - 36436579

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SN - 0045-6535

VL - 313

JO - Chemosphere

JF - Chemosphere

M1 - 137371

ER -

Characteristics of nitrogen distribution and its response to microecosystem changes in green infrastructure with different woody plants

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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