Leaf functional traits of Daphniphyllum macropodum across different altitudes in Mao’er Mountain in Southern China

Frontiers in Forests and Global Change Pub Date : 2024-07-17 DOI:10.3389/ffgc.2024.1359361

Zhangting Chen, Qiaoyu Li, Zhaokun Jiang, Pengbo Yan, Muhammad Arif

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Abstract

Investigating functional traits among mountain species with differing altitude requirements is integral to effective conservation practices. Our study aims to investigate the structural and chemical characteristics of Daphniphyllum macropodum leaves at three altitudes (1100 m, 1300 m, and 1500 m) across southern China to provide insight into changes in leaf functional traits (LFT) as well as plant adaptations in response to changing environmental conditions. Leaf structural characteristics include leaf thickness (LT), leaf area (LA), specific leaf area (SLA), and leaf tissue density (LD), respectively, while chemical properties include carbon-nitrogen-phosphorus (C:N:P) contents and ratios, such as C/N, C/P, and N/P. Our findings demonstrated the significant effect of altitude on both structural (LT, SLA, LD) and chemical aspects (N, C/N, N/P) of LFT. In particular, leaves at 1100 and 1300 m differed greatly, with 1300 m having lower SLA values than 1100 m. Observable trends included an initial increase followed by a decline as the altitude rose. Notable among them were the LT, LD, N, and N/P values at both locations. Traits at 1300 m were significantly higher than at 1100 m; SLA and C/N values displayed an inverse trend, with their lowest values occurring at 1300 m. Furthermore, this research demonstrated various degrees of variation among LFT, with structural traits exhibiting greater fluctuation than chemical traits. Robust correlations were observed among certain traits, such as LT, LD, and SLA. Furthermore, the interdependency relationships between N and C/N, as well as P and C/P, demonstrated interconnectedness. Redundancy analysis indicated that soil factors, specifically P content, exerted the strongest impact on LFT. At 1100 m, D. macropodum employed acquisition strategies; however, at 1300 m, conservation strategies emerged, showing a shift from acquisition strategies at lower altitudes to conservative strategies at higher ones.

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华南毛儿山大叶绣线菊在不同海拔地区的叶片功能特征

对不同海拔高度要求的山地物种的功能特征进行调查是有效保护实践不可或缺的一部分。我们的研究旨在调查中国南方三个海拔高度（1100米、1300米和1500米）的大叶黄杨叶片的结构和化学特征，以深入了解叶片功能特征（LFT）的变化以及植物对环境条件变化的适应性。叶片结构特征包括叶片厚度（LT）、叶面积（LA）、比叶面积（SLA）和叶片组织密度（LD），化学特性包括碳氮磷（C:N:P）含量和比率，如 C/N、C/P 和 N/P。我们的研究结果表明，海拔高度对 LFT 的结构（LT、SLA、LD）和化学特性（N、C/N、N/P）都有显著影响。尤其是 1100 米和 1300 米处的叶片差异很大，1300 米处的 SLA 值低于 1100 米处。其中值得注意的是两地的LT、LD、N和N/P值。1300 米处的性状明显高于 1100 米处；SLA 和 C/N 值呈反向趋势，最低值出现在 1300 米处。在某些性状（如低纬度、中纬度和平均海拔高度）之间观察到了稳健的相关性。此外，氮和碳/氮以及磷和碳/磷之间的相互依存关系也显示出相互关联性。冗余分析表明，土壤因子（尤其是 P 含量）对 LFT 的影响最大。在海拔 1100 米处，大菱鲆采用的是获取策略；但在海拔 1300 米处，则出现了保护策略，这表明低海拔地区的获取策略向高海拔地区的保护策略转变。

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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Frontiers in Forests and Global Change

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