Effect of litter quality on soil microbial mechanisms in home-field advantage of litter decomposition in two subtropical forests

doi:10.1093/jpe/rtaf149

J Plant Ecol ›› 2026, Vol. 19 ›› Issue (1): rtaf149.DOI: 10.1093/jpe/rtaf149

• Research Article •

Effect of litter quality on soil microbial mechanisms in home-field advantage of litter decomposition in two subtropical forests

Dehuang Zhu1^*, Dafeng Hui^2*

¹College of Ecology and Resources Engineering, Wuyi University, Nanping 354300, China, ²Department of Biological Sciences, Tennessee State University, Nashville TN38209, USA

^*Corresponding authors. E-mail: zhudh5@mail2.sysu.edu.cn (D. Z.), dhui@Tnstate.edu (D. H.)

Received:2025-03-28 Accepted:2025-08-29 Online:2025-09-09 Published:2026-02-01
Supported by:
This study was supported by the Natural Science Foundation of Fujian Province, China (2021J05248) and the Science Foundation Project for Talented New Faculty at Wuyi University (YJ202103).

凋落物质量驱动亚热带森林凋落物分解 “主场优势” 的微生物机制

Abstract

Abstract: The home-field advantage (HFA) hypothesis posits that leaf litter decomposes faster at its native sites (‘home’) than in foreign sites (‘away’). While litter quality critically regulates decomposition and HFA, the interplay among litter quality, soil nutrients, and microbial activity in driving HFA remains poorly understood. We examined these dynamics in subtropical forests using Pinus massoniana (low-quality litter) and Schima superba (high-quality litter) in a reciprocal transplant decomposition experiment, including a 1:1 mixed-litter treatment. Our results revealed pronounced HFA effects in both forest stands, but litter quality was negatively correlated with both the decomposition rate and HFA magnitude. Soil nutrients regulated HFA effects, accounting for 56% of the variation in low-quality litter (vs. 25% for high-quality litter). Low-quality litter exhibited greater sensitivity to soil microbial metabolic activity. Soil microbial biomass enhanced HFA in the low-quality litter forest stand but suppressed it in the high-quality forest stand. Enzymatic activity (e.g. β-1,4-glucosidase) directly mediates HFA, particularly in the high-quality litter. These findings underscore litter quality as a pivotal factor governing HFA through its interactions with soil nutrients and microbial metabolism, with implications for predicting biogeochemical cycles in forest ecosystems.

This study investigated the influence of litter quality on the home-field advantage (HFA) in subtropical forests using a reciprocal transplant decomposition experiment. The results revealed that HFA was evident in both forest stands; lower-quality litter exhibited stronger HFA and greater sensitivity to soil microbial activity than high-quality litter, with soil nutrients explaining a larger proportion of the HFA variation in low-quality litter systems.

Key words: litter quality, litter decomposition, home-field advantage, soil enzyme activity, soil microbial biomass

摘要：
“主场优势” 假说认为叶片凋落物在原生环境中(本地)的分解速率高于非原生环境(异地)。凋落物质量是影响凋落物分解和主场效应的关键因素，但目前学术界尚不清楚凋落物质量、土壤养分和微生物活性之间的相互作用如何调控主场效应。本研究以亚热带森林为研究对象，采用马尾松(Pinus massoniana，低凋落物质量)和木荷(Schima superba，高凋落物质量)交互移植凋落物分解实验(包括1:1混合凋落物处理)，探究主场效应的驱动因素。结果表明：1)两种林分叶片凋落物分解均存在明显的“主场优势”效应，但凋落物质量与凋落物分解速率和主场效应强度负相关。2)土壤养分调控主场效应。在低质量凋落物中，土壤养分对主场效应的解释率为56%，而在高质量凋落物中，其解释率仅为25%。3)低质量凋落物对土壤微生物代谢活动更为敏感。在低质量凋落物林分中，土壤微生物生物量增强了主场效应，而在高质量凋落物林分中，微生物生物量则抑制了该效应；酶活性(如β-1,4-葡萄糖苷酶)直接调控主场效应，尤其是对于高质量凋落物其作用更为明显。上述发现表明，凋落物质量与土壤养分和微生物代谢互作共同影响 “主场优势” 效应，为准确预测森林生物地球化学循环提供理论依据。

关键词: 凋落物质量, 凋落物分解, 主场效应, 土壤酶活性, 土壤微生物生物量

Dehuang Zhu, Dafeng Hui. Effect of litter quality on soil microbial mechanisms in home-field advantage of litter decomposition in two subtropical forests[J]. J Plant Ecol, 2026, 19(1): 1-.

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Effect of litter quality on soil microbial mechanisms in home-field advantage of litter decomposition in two subtropical forests

凋落物质量驱动亚热带森林凋落物分解 “主场优势” 的微生物机制

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