Nitrogen and carbon supply controls tree radial growth at an alpine treeline

doi:10.1093/jpe/rtaf177

J Plant Ecol ›› Advance articles DOI:10.1093/jpe/rtaf177

• Research Article •

Nitrogen and carbon supply controls tree radial growth at an alpine treeline

Ying Guo^1,2, Lin Zhang^2*, Wei Shen², Guangshuai Cui², Yanhong Tang¹, Tianxiang Luo²

¹College of Urban and Environmental Sciences, and Key Laboratory for Earth Surface Processes of the Ministry of Education, Peking University, Beijing 100871, China

²Institute of Tibetan Plateau Research, Chinese Academy of Sciences, Beijing 100101, China

^*Corresponding Author: Dr. Lin Zhang, Professor in alpine plant ecology

Institute of Tibetan Plateau Research, Chinese Academy of Sciences, Building 3, Courtyard 16, Lin Cui Road, Chaoyang District, Beijing 100101, China Phone/Fax: +86 10 84097055; Email: zhanglin@itpcas.ac.cn

Received:2025-03-23 Accepted:2025-10-10 Online:2025-10-23 Published:2025-10-23
Supported by:
This work was supported by the National Natural Science Foundation of China [grant numbers 42401056, 41571046], the China Postdoctoral Science Foundation [grant number 2024M750068], and the 2nd Tibetan Plateau Scientific Expedition and Research Program [grant number 2019QZKK0106].

碳氮供给驱动高山林线树木径向生长

Abstract

Abstract: It is unclear whether and how tree-ring width is associated with photosynthetic productivity and nutrient recycling in forest ecosystems. Here, we aim to demonstrate how leaf turnover and nitrogen (N) resorption are crucial in regulating the seasonality of carbon (C) availability, and how tree radial growth is controlled by C supply in an alpine treeline forest. The seasonal litterfall, N resorption, leaf N concentration, leaf and twig non-structural carbohydrate (NSC) contents across eight trees were monitored every two weeks during the growing season, and radial increments were recorded by automatic dendrometers at Abies georgei var. smithii treeline. Leaf N showed a positive correlation with previous bi-weekly litterfall and N-resorption in the early season before late June, but with soil temperature in the later season. Leaf NSC typically peaked in the early growing season and showed significant relationships with previous bi-weekly litterfall and N-resorption and the following bi-weekly radial increment. There was a lagged chain from previous bi-weekly litterfall and N-resorption to current NSC in leaves, and then from current NSC in leaves to the following bi-weekly radial increment. As a significant C-storage pool, twig NSC reached a maximum in mid-July, and showed no correlation with litterfall, N-resorption and radial growth rate. N resorption and C supply regulated by leaf turnover controls tree radial growth at the alpine treeline. Our results highlight the significant role of nitrogen recycling and leaf source NSC production in driving tree radial growth, as compared to stored NSC.

Key words: litterfall, nitrogen resorption, radial growth, non-structural carbohydrate, leaf turnover, treeline forest

摘要：
目前尚不清楚树轮宽度与森林生态系统光合生产力及养分循环之间是否以及如何关联。本研究旨在揭示在高山林线森林中叶周转和氮（N）重吸收在调控碳（C）可利用性季节变化中如何发挥关键作用，以及树木径向生长如何受碳供给的调控。本研究在青藏高原东南部色季拉山急尖长苞冷杉林线选取8株样木，于生长季内每两周监测一次季节凋落物量、N重吸收量、叶N含量、以及叶和小枝的非结构性碳水化合物（NSC）含量，同时使用树木径向生长自动监测仪记录样木径向生长量。研究发现，叶N含量在生长季早期（6月底前）与前两周的凋落物量和N重吸收量正相关，但在生长季后期则与土壤温度相关。叶NSC含量普遍在生长季早期达到高峰，其动态与前两周的凋落物量和N重吸收量以及后两周的径向生长量分别呈现出显著相关性。从前两周凋落物量和N重吸收量，到当前叶NSC含量，再到后两周的径向生长量形成了一条滞后关系链。作为一个重要的碳储存库，小枝NSC含量在7月中旬最高，其动态与凋落物量、N重吸收量和径向生长速率均无显著相关性。研究表明，由叶周转调控的N重吸收和碳供给主导着高山林线树木的径向生长。相较于储存的NSC，本研究结果凸显了氮循环和叶片来源的NSC生产在驱动树木径向生长中的关键作用。

关键词: 凋落物量, 氮重吸收, 径向生长, 非结构性碳水化合物, 叶周转, 林线森林

Ying Guo, Lin Zhang, Wei Shen, Guangshuai Cui, Yanhong Tang, Tianxiang Luo. Nitrogen and carbon supply controls tree radial growth at an alpine treeline[J]. J Plant Ecol, DOI: 10.1093/jpe/rtaf177.

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Nitrogen and carbon supply controls tree radial growth at an alpine treeline

碳氮供给驱动高山林线树木径向生长

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