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在花旗松外生菌根中碳-13 和氮-15 转移的氮施肥田间研究。

A nitrogen fertilization field study of carbon-13 and nitrogen-15 transfers in ectomycorrhizas of Pinus sabiniana.

机构信息

Department of Land, Air and Water Resources, University of California, Davis, One Shields Avenue, Davis, CA, 95616, USA,

出版信息

Oecologia. 2013 Dec;173(4):1439-50. doi: 10.1007/s00442-013-2734-4. Epub 2013 Aug 4.

DOI:10.1007/s00442-013-2734-4
PMID:23912260
Abstract

Ectomycorrhizal (EM) fungi form relationships with higher plants; plants transfer C to fungi, and fungi transfer nutrients to their host. While evidence indicates that this interaction is largely mutualistic, less is known about how nutrient supply and EM associates may alter C and nutrient exchanges, especially in intact plant-soil-microbe systems in the field. In a dual-labeling experiment with N fertilization, we used C and N stable isotopes to examine in situ transfers in EM pine trees in a Pinus sabiniana woodland in northern California. We added (15)NH4SO2 and (13)CO2 to track (13)C transfer from pine needles to EM roots and (15)N transfer from soil to EM roots and pine needles. Transfers of (13)C and (15)N differed with EM morphotype and with N fertilization. The brown morphotype received the least C per unit of N transferred (5:1); in contrast red and gold morphotypes gained more C and transferred less N (17:1 and 25:1, respectively). N fertilization increased N retention by ectomycorrhizas (EMs) but did not increase N transfer from EMs to pine needles. Therefore N fertilization positively affected both nutrient and C gains by EMs, increasing net C flows and N retention in EMs. Our work on intact and native trees/EM associations thereby extends earlier conclusions based on pot studies with young plants and culturable EM fungi; our results support the concept that EM-host relationships depend on species-level differences as well as responses to soil resources such as N.

摘要

外生菌根(EM)真菌与高等植物形成共生关系;植物将 C 转移给真菌,真菌将养分转移给宿主。虽然有证据表明这种相互作用在很大程度上是互利的,但对于养分供应和 EM 共生体如何改变 C 和养分交换,尤其是在野外完整的植物-土壤-微生物系统中,人们知之甚少。在一项氮施肥的双重标记实验中,我们使用 C 和 N 稳定同位素,在加利福尼亚北部的一种狐尾松林地的 EM 松树上,研究了原位转移。我们添加了 (15)NH4SO2 和 (13)CO2,以追踪来自松树针叶的 (13)C 向 EM 根系的转移,以及来自土壤的 (15)N 向 EM 根系和松树针叶的转移。(13)C 和 (15)N 的转移随 EM 形态和氮施肥而不同。棕色形态的氮转移比最小(5:1);相比之下,红色和金色形态获得更多的 C,转移更少的 N(17:1 和 25:1)。氮施肥增加了外生菌根(EM)的氮保留,但并没有增加 EM 向松树针叶的氮转移。因此,氮施肥对 EM 的养分和 C 获得都有积极影响,增加了 EM 中的净 C 流和氮保留。我们对完整和原生树木/EM 关联的研究,因此扩展了早期基于盆栽研究年轻植物和可培养 EM 真菌的结论;我们的结果支持这样一种概念,即 EM-宿主关系不仅取决于物种水平的差异,还取决于对土壤资源(如氮)的反应。

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