J Plant Ecol ›› Advance articles     DOI:10.1093/jpe/rtag139

• Research Article •     Next Articles

Divergence in leaf versus root decomposition in three Stipa species along a grassland grazing exclusion gradient

Lixin Yu 1, Rui Tian 1, Ruolin Zhao 1, Menghan Niu 1, Zekai Yang 1, Jishuai Su 1,2*, Yi Zhang 3,4*, Guanghua Jing 5, Jimin Cheng 4, Heyong Liu 1,2, Yong Jiang 1,2   

  1. 1 College of Life Sciences, Hebei University, Baoding, Hebei 071002, China
    2 Engineering Research Center of Ecological Safety and Conservation in Beijing-Tianjin-Hebei (Xiong’an New Area) of MOE, Hebei University, Baoding, Hebei 071002, China
    3 School of Chemical Engineering and Biotechnology, Xingtai University, Xingtai, Hebei 054001, China
    4 Institute of Soil and Water Conservation, Chinese Academy of Sciences and Ministry of Water Resources, Yangling, Shaanxi 712100, China
    5 Key Laboratory of Soil Resource & Biotech Application, Shaanxi Academy of Sciences, Institute of Botany of Shaanxi Province, Xi'an Botanical Garden of Shaanxi Province, Xi'an, Shaanxi 710061, China
    *Correspondence address:
    Jishuai Su, College of Life Sciences, Hebei University, Baoding, Hebei 071002, China Email: sujishuai@hbu.edu.cn
    Yi Zhang, School of Chemical Engineering and Biotechnology, Xingtai University, Xingtai 054001, China Email: zhangy2681@163.com
  • Received:2025-12-02 Accepted:2026-06-02 Published:2026-06-12
  • Supported by:
    This work was supported by Hebei Natural Science Foundation, China (C2024201064), the National Natural Science Foundation of China (32471647 and 31901139), and the Excellent Youth Research Innovation Team of Hebei University (QNTD202409).

三种针茅属植物沿草地围封梯度的叶片与根系分解差异

Abstract: Litter decomposition is a critical driver of carbon and nutrient cycling in terrestrial ecosystems. Numerous studies have demonstrated that plant litter typically decomposes faster in its native habitat (‘home’) than in foreign environments (‘away’), known as the home-field advantage (HFA). Much of our understanding of the HFA effect arises from leaf litter decomposition in forest ecosystems, how HFA regulates the decomposition of leaf and root litters in grasslands remains unclear. We performed a reciprocal litter transplant experiment using leaf and root materials from three Stipa species (Stipa bungeana, Stipa grandis, and Stipa przewalskyi) that dominate semi-arid grassland sites with different grazing exclusion durations (5, 15, and 32 years). Generally, we found no HFA effect for either leaf or root decomposition across the three Stipa species. Litter type and plant identity interactively affected the decomposition rate: roots decomposed slower than leaves in S. bungeana and S. grandis, while decomposition rates of roots and leaves were similar in S. przewalskyi. Notably, compared with the other two species, S. przewalskyi exhibited faster root decomposition and slower leaf decomposition. Our results demonstrated that, in terms of litter decomposition traits of dominant species, leaf decomposition decreased with longer grazing exclusion duration, while root decomposition rates increased. In addition, litter carbon and nitrogen losses exhibited stronger stoichiometric coupling in leaves compared to roots. Our findings provide little evidence for HFA effects in enclosed grasslands. Instead, shifts in dominant species lead to distinct temporal patterns in leaf versus root decomposition along the grazing exclusion chronosequence, providing new insights into above- and belowground C and N dynamics during grassland restoration.

Grazing exclusion-induced species turnover alters the decomposition processes of leaves and roots in grasslands. This study found that, despite the lack of a pronounced home-field advantage effect in the decomposition of leaves and roots from dominant species in enclosed grasslands, leaf decomposition rate decreased while root decomposition rates increased over time, based on the litter decomposition characteristics of these dominant species.

Key words: home-field advantage, grassland, grazing exclusion, leaf litter decomposition, root decomposition

摘要:
凋落物分解是陆地生态系统碳和养分循环的关键驱动过程。大量研究表明,植物凋落物在其原生生境(“主场”)中的分解速度通常快于异地生境的分解速度,这一现象被称为“主场优势”(home-field advantage, HFA)。目前对HFA效应的理解主要来源于森林生态系统的叶片凋落物分解研究,尚不清楚HFA如何调控草地生态系统叶片和根系凋落物分解过程。本研究以三种针茅属植物(长芒草(Stipa bungeana)、大针茅(Stipa grandis)、甘青针茅(Stipa przewalskyi))为对象,它们分别主导不同围封时间(5、15和32年)的半干旱草地群落。我们利用这三种针茅叶片和根系材料开展了交互移植分解实验。总体而言,三种针茅叶片和根系分解均未表现出明显的HFA效应。凋落物类型与物种身份对分解速率存在交互作用,其中长芒草和大针茅根系分解慢于叶片,而甘青针茅根系与叶片的分解速率相近。值得注意的是,相比于另外两种针茅植物,甘青针茅表现出更快的根系分解和更慢的叶片分解。从优势种凋落物分解特性角度来看,随着围封时间延长,草地叶片分解速率降低,而根系分解速率升高。此外,叶片凋落物碳和氮的损失表现出比根系更强的化学计量耦合关系。综上所述,围封草地凋落物分解并未表现出明显主场优势效应。然而,在草地围封时间序列上,优势种的更替导致了叶片与根系分解呈现不同的时间变化模式,这为理解草地恢复过程中地上与地下碳氮动态提供了新的认识。

关键词: 主场优势, 草地, 围栏封育, 叶片凋落物分解, 根系分解