Leaf nitrogen and phosphorus are more sensitive to environmental factors in dicots than in monocots, globally.

IF 4.6 1区生物学 Q1 PLANT SCIENCES Plant Diversity Pub Date : 2024-08-05 eCollection Date: 2024-11-01 DOI:10.1016/j.pld.2024.08.002

Miao Liu, Tiancai Zhou, Quansheng Fu

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Abstract

Leaf nitrogen (N) and phosphorus (P) levels provide critical strategies for plant adaptions to changing environments. However, it is unclear whether leaf N and P levels of different plant functional groups (e.g., monocots and dicots) respond to environmental gradients in a generalizable pattern. Here, we used a global database of leaf N and P to determine whether monocots and dicots might have evolved contrasting strategies to balance N and P in response to changes in climate and soil nutrient availability. Specifically, we characterized global patterns of leaf N, P and N/P ratio in monocots and dicots, and explored the sensitivity of stoichiometry to environment factors in these plants. Our results indicate that leaf N and P levels responded to environmental factors differently in monocots than in dicots. In dicots, variations of leaf N, P and N/P ratio were significantly correlated to temperature and precipitation. In monocots, leaf N/P ratio was not significantly affected by temperature or precipitation. This indicates that leaf N, P and N/P ratio are less sensitive to environmental dynamics in monocots. We also found that in both monocots and dicots N/P ratios are associated with the availability of soil total P rather than soil total N, indicating that P limitation on plant growth is pervasive globally. In addition, there were significant phylogenetic signals for leaf N (λ = 0.65), P (λ = 0.57) and N/P ratio (λ = 0.46) in dicots, however, only significant phylogenetic signals for leaf P in monocots. Taken together, our findings indicate that monocots exhibit a "conservative" strategy (high stoichiometric homeostasis and weak phylogenetic signals in stoichiometry) to maintain their growth in stressful conditions with lower water and soil nutrients. In contrast, dicots exhibit lower stoichiometric homeostasis in changing environments because of their wide climate-soil niches and significant phylogenetic signals in stoichiometry.

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在全球范围内，双子叶比单子叶对环境因子更敏感。

叶片氮（N）和磷（P）水平是植物适应环境变化的关键策略。然而，目前还不清楚不同植物功能群（如单子叶植物和双子叶植物）的叶片氮和磷水平是否以一种普遍的模式对环境梯度做出反应。在这里，我们利用叶片氮和磷的全球数据库来确定单子叶植物和双子叶植物是否可能进化出不同的策略来平衡氮和磷，以应对气候和土壤养分供应的变化。具体来说，我们描述了单子叶植物和双子叶植物叶片氮、磷和氮磷比的全球模式，并探讨了这些植物的化学计量对环境因素的敏感性。我们的研究结果表明，单子叶植物的叶片氮和磷水平对环境因素的反应与双子叶植物不同。在双子叶植物中，叶片氮、磷和氮磷比的变化与温度和降水量有显著的相关性。在单子叶植物中，叶片氮磷比受温度和降水的影响不明显。这表明单子叶植物的叶片氮、磷和氮磷比对环境动态的敏感性较低。我们还发现，在单子叶植物和双子叶植物中，N/P 比与土壤总磷的可用性而不是土壤总氮的可用性有关，这表明全球范围内植物生长普遍受到磷的限制。此外，在双子叶植物中，叶片氮（λ = 0.65）、磷（λ = 0.57）和氮磷比（λ = 0.46）存在显著的系统发育信号，但在单子叶植物中，只有叶片磷存在显著的系统发育信号。综上所述，我们的研究结果表明，单子叶植物表现出一种 "保守 "策略（较高的化学计量平衡和化学计量方面较弱的系统发生学信号），以维持其在水分和土壤养分较低的胁迫条件下的生长。与此相反，双子叶植物在不断变化的环境中表现出较低的化学计量平衡，因为它们具有广泛的气候-土壤壁龛，而且在化学计量方面具有显著的系统发生学信号。

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

Plant Diversity Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics

CiteScore

8.30

自引率

6.20%

发文量

1863

审稿时长

35 days

期刊介绍： Plant Diversity (formerly Plant Diversity and Resources) is an international plant science journal that publishes substantial original research and review papers that advance our understanding of the past and current distribution of plants, contribute to the development of more phylogenetically accurate taxonomic classifications, present new findings on or insights into evolutionary processes and mechanisms that are of interest to the community of plant systematic and evolutionary biologists. While the focus of the journal is on biodiversity, ecology and evolution of East Asian flora, it is not limited to these topics. Applied evolutionary issues, such as climate change and conservation biology, are welcome, especially if they address conceptual problems. Theoretical papers are equally welcome. Preference is given to concise, clearly written papers focusing on precisely framed questions or hypotheses. Papers that are purely descriptive have a low chance of acceptance. Fields covered by the journal include: plant systematics and taxonomy- evolutionary developmental biology- reproductive biology- phylo- and biogeography- evolutionary ecology- population biology- conservation biology- palaeobotany- molecular evolution- comparative and evolutionary genomics- physiology- biochemistry