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暖温带森林中树冠层和灌木层叶片对树冠层氮添加和水分添加的不同响应

Different responses of canopy and shrub leaves to canopy nitrogen and water addition in warm temperate forest.

作者信息

Li Mengke, Sun Ruomin, He Yaqi, Zhou Tenglong, Mao Jianing, Li Wen, Liu Chang, Ma Lei, Fu Shenglei

机构信息

College of Geographical Sciences, Faculty of Geographic Science and Engineering, Henan University, Zhengzhou, China.

Dabieshan National Observation and Research Field Station of Forest Ecosystem at Henan, Kaifeng, China.

出版信息

Front Plant Sci. 2025 Apr 14;16:1530588. doi: 10.3389/fpls.2025.1530588. eCollection 2025.

DOI:10.3389/fpls.2025.1530588
PMID:40297727
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12034683/
Abstract

INTRODUCTION

Understanding the effects of nitrogen deposition and increased rainfall on plants is critical for maintaining forest ecosystem services. Although previous studies primarily examined the effects of environmental changes on leaf functional traits, the underlying physiological and metabolic processes associated with these traits remain poorly understood and warrant further investigation.

METHODS

To address this knowledge gap, we evaluated the influence of canopy nitrogen (25 kg ha yr) and water (30% of the local precipitation) addition on leaf functional traits, diversity, and associated physiological and metabolic processes in the dominant species of tree and shrub layers.

RESULTS

Only the interaction between nitrogen and water significantly reduced the functional richness (FRic) of the community. The other treatments had no notable effects on functional diversity. Importantly, the physiological processes of trees and shrubs showed different regulatory strategies. In addition, there were significant changes in 29 metabolic pathways of the tree, whereas only 18 metabolic pathways were significantly altered in shrub. Among the identified metabolic pathways, four were annotated multiple times, with amino acid metabolism being the most active.

DISCUSSION

These regulatory processes enable the leaves to withstand external disturbances and maintain their relative stability under changing environmental conditions. The study findings underscore the limitations of previous research, which often relied on the direct application of treatments to the understory and so failed to accurately assess the effects of nitrogen and water on leaf functional traits. Future studies should adopt canopy-level nitrogen and water addition to better simulate the impacts of global environmental change.

摘要

引言

了解氮沉降和降雨增加对植物的影响对于维持森林生态系统服务至关重要。尽管先前的研究主要考察了环境变化对叶片功能性状的影响,但与这些性状相关的潜在生理和代谢过程仍知之甚少,值得进一步研究。

方法

为填补这一知识空白,我们评估了树冠层添加氮(25千克·公顷·年)和水(当地降水量的30%)对乔木层和灌木层优势物种的叶片功能性状、多样性以及相关生理和代谢过程的影响。

结果

只有氮和水的交互作用显著降低了群落的功能丰富度(FRic)。其他处理对功能多样性没有显著影响。重要的是,乔木和灌木的生理过程表现出不同的调节策略。此外,乔木有29条代谢途径发生了显著变化,而灌木只有18条代谢途径发生了显著改变。在已确定的代谢途径中,有四条被多次注释,其中氨基酸代谢最为活跃。

讨论

这些调节过程使叶片能够抵御外部干扰,并在不断变化的环境条件下保持相对稳定。研究结果强调了先前研究的局限性,这些研究往往直接对林下植被进行处理,从而未能准确评估氮和水对叶片功能性状的影响。未来的研究应采用树冠层添加氮和水的方法,以更好地模拟全球环境变化的影响。

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