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在胁迫下,通过鉴定外生菌根真菌组合中的功能来获取氮。

Attributing functions to ectomycorrhizal fungal identities in assemblages for nitrogen acquisition under stress.

机构信息

Forest Botany and Tree Physiology, Georg-August Universität Göttingen, Büsgenweg 2, Göttingen, Germany.

出版信息

ISME J. 2014 Feb;8(2):321-30. doi: 10.1038/ismej.2013.158. Epub 2013 Sep 12.

DOI:10.1038/ismej.2013.158
PMID:24030593
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3906819/
Abstract

Mycorrhizal fungi have a key role in nitrogen (N) cycling, particularly in boreal and temperate ecosystems. However, the significance of ectomycorrhizal fungal (EMF) diversity for this important ecosystem function is unknown. Here, EMF taxon-specific N uptake was analyzed via (15)N isotope enrichment in complex root-associated assemblages and non-mycorrhizal root tips in controlled experiments. Specific (15)N enrichment in ectomycorrhizas, which represents the N influx and export, as well as the exchange of (15)N with the N pool of the root tip, was dependent on the fungal identity. Light or water deprivation revealed interspecific response diversity for N uptake. Partial taxon-specific N fluxes for ectomycorrhizas were assessed, and the benefits of EMF assemblages for plant N nutrition were estimated. We demonstrated that ectomycorrhizal assemblages provide advantages for inorganic N uptake compared with non-mycorrhizal roots under environmental constraints but not for unstressed plants. These benefits were realized via stress activation of distinct EMF taxa, which suggests significant functional diversity within EMF assemblages. We developed and validated a model that predicts net N flux into the plant based on taxon-specific (15)N enrichment in ectomycorrhizal root tips. These results open a new avenue to characterize the functional traits of EMF taxa in complex communities.

摘要

菌根真菌在氮(N)循环中起着关键作用,特别是在北方和温带生态系统中。然而,外生菌根真菌(EMF)多样性对这一重要生态系统功能的意义尚不清楚。在这里,通过(15)N 同位素在复杂的根相关组合和非菌根根尖中的富集,分析了外生菌根真菌的分类群特异性 N 吸收。外生菌根中特定的(15)N 富集,代表了 N 的流入和流出,以及与根尖 N 库的(15)N 交换,取决于真菌的身份。光或水分胁迫揭示了 N 吸收的种间响应多样性。评估了外生菌根中部分分类群特异性 N 通量,并估计了 EMF 组合对植物 N 营养的益处。我们证明,在外生菌根组合在环境胁迫下比非菌根根具有无机 N 吸收优势,但在未受胁迫的植物中则没有。这些好处是通过特定的 EMF 类群的应激激活实现的,这表明 EMF 组合内存在显著的功能多样性。我们开发并验证了一个模型,该模型基于外生菌根根尖中特定分类群的(15)N 富集,预测了净 N 流入植物的情况。这些结果为在复杂群落中表征 EMF 分类群的功能特征开辟了一条新途径。

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