Relationships between denitrification rates and functional gene abundance in a wetland: The roles of single- and multiple-species plant communities

Wetland soil denitrification removes excess inorganic nitrogen (N) and prevents eutrophication in aquatic ecosystems. Wetland plants have been considered the key factors determining the capacity of wetland soil denitrification to remove N pollutants in aquatic ecosystems. However, the influences of...

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Bibliographic Details
Published in:The Science of the total environment 2023-03, Vol.863, p.160913, Article 160913
Main Authors: Kong, Yushuang, Zhang, Haikuo, Tian, Linlin, Yuan, Junji, Chen, Youchao, Li, Yan, Chen, Jian, Chang, Scott X., Fang, Yunying, Tavakkoli, Ehsan, Cai, Yanjiang
Format: Article
Language:English
Subjects:
Denitrification
Ecosystem
Environmental Pollutants
Eutrophication
Nitrates
Nitrogen
Plant biomass
Plants
Poaceae
Single planting
Soil - chemistry
Soil Microbiology
Two-plant communities
Wetland soil denitrification
Wetlands
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Summary:Wetland soil denitrification removes excess inorganic nitrogen (N) and prevents eutrophication in aquatic ecosystems. Wetland plants have been considered the key factors determining the capacity of wetland soil denitrification to remove N pollutants in aquatic ecosystems. However, the influences of various plant communities on wetland soil denitrification remain unknown. In the present study, we measured variations in soil denitrification under different herbaceous plant communities including single Phragmites karka (PK), single Paspalum thunbergia (PT), single Zizania latifolia (ZL), a mixture of Paspalum thunbergia plus Phragmites karka (PTPK), a mixture of Paspalum thunbergia plus Zizania latifolia (PTZL), and bare soil (CK) in the Estuary of Nantiaoxi River, the largest tributary of Qingshan Lake in Hangzhou, China. The soil denitrification rate was significantly higher in the surface (0–10 cm) than the subsurface (10–20 cm) layer. Wetland plant growth increased the soil denitrification rate by significantly increasing the soil water content, nitrate concentration, and ln(nirS) + ln(nirK). A structural equation model (SEM) showed that wetland plants indirectly regulated soil denitrification by altering the aboveground and belowground plant biomass, nitrate concentration, abundances of denitrifying functional genes, and denitrification potential. There was no significant difference in soil denitrification rates among PT, PK and ZL. The soil denitrification rate was significantly lower in PTZL than PTPK. Two-plant communities did not necessarily enhance the denitrification rate compared to single planting, the former had a greater competitiveness on N uptake and consequently reduced the amount of nitrate available for denitrification. As PTPK had the highest denitrification rate, co-planting P. thunbergia and P. karka could effectively improve N removal efficiency and help mitigate eutrophication in adjacent aquatic ecosystems. The results of this investigation provide useful information guiding the selection of appropriate wetland herbaceous plant species for wetland construction and the removal of N pollutants in aquatic ecosystems. [Display omitted] •The soil denitrification rate was higher at the soil surface than the subsurface.•Plant growth significantly increased the soil denitrification rate.•Two-plant community did not enhance denitrification compared with single planting.•Plant biomass was correlated with soil NO3−-N and denitrifying functional
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2022.160913