Interactive effects of nitrogen fertilizer and altered precipitation on fungal communities in arid grasslands of northern China

Purpose Fungi play an essential role in regulating the functioning of terrestrial ecosystems and are sensitive to climate change factors. Climate change incidents, such as N deposition and altered precipitation, create abiotic stress regarding the water use efficiency of soil and nutrient limitation...

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Bibliographic Details
Published in:Journal of soils and sediments 2020-03, Vol.20 (3), p.1344-1356
Main Authors: Wang, Hai, Ta, Na, Jin, Ke, Ji, Baoming, Schellenberg, Michael P., Wei, Zhijun, Wang, Zhen
Format: Article
Language:English
Subjects:
Aridity
Ascomycota
Biological fertilization
Biomass
Climate change
Community composition
Composition effects
Deserts
Earth and Environmental Science
Environ Risk Assess
Environment
Environmental Physics
Fertilization
Fertilizers
Functional groups
Fungi
Grasslands
Limiting factors
Mathematical models
Multivariate statistical analysis
Next-generation sequencing
Nitrogen
Pathogens
Planting density
Precipitation
Sec 2 • Global Change
Soil chemistry
Soil microorganisms
Soil pH
Soil properties
Soil Science & Conservation
Soil water
Soils
Steppes
Sustainable Land Use • Research Article
Terrestrial ecosystems
Water use
Water use efficiency
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Summary:Purpose Fungi play an essential role in regulating the functioning of terrestrial ecosystems and are sensitive to climate change factors. Climate change incidents, such as N deposition and altered precipitation, create abiotic stress regarding the water use efficiency of soil and nutrient limitation impacting the activity of soil fungi. This study aimed to examine the combined effects of N fertilization and altered precipitation on soil fungal diversity and composition in the desert steppe. Materials and methods In the present study, we carried out a field experiment to assess the soil fungal diversity and composition of the desert steppe in response to N fertilizer (0 or 35 kg N ha −1 year −1 ) and precipitation changes (control, − 50% precipitation, or + 50% precipitation) in the desert steppe. The study was initiated in 2012, and plant and soil samples were collected after 5 years (August, 2017) of field treatments. High-throughput sequencing was applied to estimate the fungal diversity and composition. Results and discussion The soil fungal communities were dominated by Ascomycota (87.85% ± 1.26%), which primarily drove the fungal community composition. Decreased precipitation promoted strong shifts in fungal community composition under both N fertilizer levels. Increased precipitation significantly reduced Shannon-Wiener indices by 9.96%. The increasing relative abundances of fungal functional groups (lichenized saprotroph, animaland plant pathogens) resulted in a marked shift in fungal community composition from decreased precipitation to increased precipitation, which is attributed to the important role of the Ascomycota phylum in fungal communities. Structural equation modeling (SEM) indicated that C 4 biomass was the predominant factor determining the Shannon-Wiener index for these fungi. Direct altered precipitation, indirect soil pH, and C 4 biomass together controlled soil fungal community composition, with altered precipitation as the main driver. Conclusions The interactive effects of N fertilizer and altered precipitation on grassland plant density, biomass, and soil properties may play an essential role in determining fungal diversity and community composition. Precipitation is a primary limiting factor that influences fungal community composition. Effects of N fertilizer on soil fungal community composition are highly dependent on changes in precipitation.
ISSN:1439-0108
1614-7480
DOI:10.1007/s11368-019-02512-2