Arbuscular mycorrhizal fungal communities associated with two dominant species differ in their responses to long-term nitrogen addition in temperate grasslands

Arbuscular mycorrhizal (AM) fungi are important components of grassland ecosystems and are sensitive to enhanced atmospheric nitrogen (N) deposition. Enhanced N deposition has been widely reported to reduce species richness and alter species composition across different types of grasslands world‐wid...

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Published in:Functional ecology 2018-06, Vol.32 (6), p.1575-1588
Main Authors: Zheng, Zhi, Ma, Pengfei, Li, Juan, Ren, Lifei, Bai, Wenming, Tian, Qiuying, Sun, Wei, Zhang, Wen-Hao
Format: Article
Language:English
Subjects:
arbuscular mycorrhizal fungi
Arbuscular mycorrhizas
Artemisia frigida
Biomass
carbon allocation
Colonization
COMMUNITY ECOLOGY
Density
Deposition
Dominant species
Flowers & plants
Fungi
Grasslands
Host plants
Manganese
Nitrogen
nitrogen enrichment
Nutrients
Photosynthesis
photosynthetic rates
Reduction
Rhizosphere
Roots
soil acidification
soil manganese and iron
Soil properties
Species composition
Species richness
Steppes
Stipa krylovii
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Summary:Arbuscular mycorrhizal (AM) fungi are important components of grassland ecosystems and are sensitive to enhanced atmospheric nitrogen (N) deposition. Enhanced N deposition has been widely reported to reduce species richness and alter species composition across different types of grasslands world‐wide. Despite extensive studies on effects of N deposition on AM fungal communities of grasslands, few studies have specifically focused on effects of N deposition on AM fungi associated with dominant species in grasslands. We investigated long‐term (12‐year) effects of N addition (80 kg ha−1 year−1) on AM fungal community richness in roots and rhizosphere biomass of two dominant plant species (forb Artemisia frigida and grass Stipa krylovii) in temperate steppes of northern China. We found that AM fungi associated with the two dominant plant species differed in their responses to N addition. Nitrogen addition led to a significant reduction in AM fungal richness colonized in roots, and biomass in the rhizosphere of A. frigida, while N addition had little impacts on AM fungi colonized in roots and rhizosphere of S. krylovii. Nitrogen addition significantly reduced AM fungal colonization in roots and AM fungal spore density in the rhizosphere soils of A. frigida. In contrast, N addition had no effect on AM fungal colonization in roots and spore density in the rhizosphere of S. krylovii. Nitrogen addition markedly suppressed photosynthetic rates in A. frigida due to excessive foliar accumulation of manganese. The N‐induced reduction in photosynthetic rates reduced allocation of C into roots in A. frigida, leading to a lower root/shoot ratio, and suppression of AM fungal community associated with A. frigida. The inhibition of AM fungi would render A. frigida less competitive in terms of acquisition of mineral nutrients in soils, thus contributing to its loss in the steppe community under conditions of elevated N deposition. These findings provide a mechanistic explanation for N‐evoked differential responses of AM fungal communities associated with A. frigida and S. krylovii by linking soil properties and host plants to AM fungal communities. A plain language summary is available for this article. Plain Language Summary
ISSN:0269-8463
1365-2435
DOI:10.1111/1365-2435.13081