Plant Nitrogen Preferences Mirror Underground Nitrogen Cycling in Natural Ecosystems

IF 12 1区环境科学与生态学 Q1 BIODIVERSITY CONSERVATION

Global Change Biology Pub Date : 2025-10-15 DOI:10.1111/gcb.70546

Ahmed S. Elrys, Lei Meng, Yves Uwiragiye, Khaled A. El-Tarabily, Qilin Zhu, Xiaoqian Dan, Tang Shuirong, Wu Yanzheng, Yanfu Bai, Tong-bin Zhu, Jinbo Zhang, Christoph Müller

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Abstract

Reliable prediction of plant nitrogen (N) acquisition strategies is critical for interpreting ecosystem productivity. We propose a process-based framework that connects plant N preferences to soil microbial N cycling and environmental conditions. We compiled data from 66 ¹⁵N labeling studies, yielding 336 triplet observations, each consisting of plant organic-N, ammonium-N, and nitrate-N uptake measurements (Dataset 1). Additionally, 2030 observations of gross soil N transformations from 270 studies were compiled to predict the spatial variation of these rates globally, with the aim of populating Dataset 1. We found that ammonium-N was the primary contributor to N uptake in forests (49% ± 1.84%) and wetlands (55% ± 3.29%), whereas nitrate-N was the dominant source in grasslands (41% ± 1.52%). Plant ammonium-N and nitrate-N preferences were lowest in temperate and tropical regions, respectively. Nitrification capacity—autotrophic nitrification (the process where ammonium is oxidized to nitrate) to gross N mineralization (GNM; the conversion of organic N to ammonium) ratio—was the main regulator of plant ammonium-N and nitrate-N preferences. Terrestrial environments with high nitrification capacity (e.g., temperate or grassland soils) resulting from high soil pH and low carbon-to-N ratio exhibited higher plant nitrate-N preference, while adverse conditions (e.g., tropical, forest, or wetland soils) exhibited higher ammonium-N preference. Interestingly, dissimilatory nitrate reduction to ammonium (DNRA) process redirected plant preference toward ammonium-based nutrition in organic carbon-rich, low-oxygen soils. Climate-driven shifts in plant N preference are mediated by gross soil N transformations, as increased precipitation and/or temperature accelerated GNM and/or DNRA while inhibiting nitrification capacity, promoting plant ammonium preference. Soil N cycling and environmental conditions explained little variation in plant organic-N preference, suggesting that other variables (e.g., mycorrhizal associations and plant functional traits) may be at play. We highlight that plant N acquisition is not purely plant-driven, but it mirrors underground N transformations, with environmental conditions acting as pivotal modulators of this relationship.

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植物对氮的偏好反映了自然生态系统中的地下氮循环。

植物氮素获取策略的可靠预测是解释生态系统生产力的关键。我们提出了一个基于过程的框架，将植物氮偏好与土壤微生物氮循环和环境条件联系起来。我们收集了66项15N标记研究的数据，产生了336个三重态观察结果，每个观察结果由植物有机氮、氨氮和硝酸盐氮吸收测量组成（数据集1）。此外，我们还收集了270项研究的2030次土壤总氮转化观测数据，以预测这些速率在全球范围内的空间变化，目的是填充数据集1。结果表明，氨氮是森林（49%±1.84%）和湿地（55%±3.29%）氮吸收的主要来源，而硝酸盐氮是草原（41%±1.52%）氮吸收的主要来源。植物对铵态氮和硝态氮的偏好分别在温带和热带地区最低。硝化能力——自养硝化（氨氧化为硝态氮的过程）与总氮矿化（GNM；有机氮向铵态氮的转化）比是植物氨氮和硝态氮偏好的主要调节因子。高pH值和低碳氮比导致硝化能力强的陆地环境（如温带或草地土壤）表现出较高的植物硝酸盐氮偏好，而不利条件（如热带、森林或湿地土壤）表现出较高的植物氨氮偏好。有趣的是，在富含有机碳、低氧的土壤中，硝酸盐异化还原为铵（DNRA）过程使植物对氨基营养的偏好发生了改变。气候驱动的植物氮偏好变化是由土壤总氮转化介导的，因为降水和/或温度的增加加速了GNM和/或DNRA，同时抑制了硝化能力，促进了植物铵偏好。土壤氮循环和环境条件解释了植物有机氮偏好的微小变化，这表明其他变量（如菌根关联和植物功能性状）可能起作用。我们强调植物氮的获取不完全是植物驱动的，但它反映了地下氮的转换，环境条件是这种关系的关键调制器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Global Change Biology 环境科学-环境科学

CiteScore

21.50

自引率

5.20%

发文量

497

审稿时长

3.3 months

期刊介绍： Global Change Biology is an environmental change journal committed to shaping the future and addressing the world's most pressing challenges, including sustainability, climate change, environmental protection, food and water safety, and global health. Dedicated to fostering a profound understanding of the impacts of global change on biological systems and offering innovative solutions, the journal publishes a diverse range of content, including primary research articles, technical advances, research reviews, reports, opinions, perspectives, commentaries, and letters. Starting with the 2024 volume, Global Change Biology will transition to an online-only format, enhancing accessibility and contributing to the evolution of scholarly communication.