Soil chemistry exerts a more significant influence on bacterial responses to nitrogen disturbances than root exudates

doi:10.1093/jpe/rtaf107

J Plant Ecol ›› 2025, Vol. 18 ›› Issue (6): rtaf107.DOI: 10.1093/jpe/rtaf107

• Research Article •

Soil chemistry exerts a more significant influence on bacterial responses to nitrogen disturbances than root exudates

Fangling Ma^1,2, Yao Zheng^1,2, La Wei^1,2, Lin Xiang^1,2, Lifei Ren¹, Wenming Bai¹, , Qiuying Tian^3,*, and Wen-Hao Zhang^1,2

¹Key Laboratory of Vegetation and Environmental Change, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China, ²College of Resource and Environment, University of Chinese Academy of Sciences, Beijing 100049, China, ³Key of Laboratory of Ecology and Resource Use of the Mongolian Plateau Ministry of Education of China, School of Ecology and Environment, Inner Mongolia University, Hohhot 010021, China

^*Corresponding author. E-mail: qytian@imu.edu.c

Received:2025-04-21 Accepted:2025-06-30 Online:2025-07-12 Published:2025-12-01
Supported by:
This study was funded by the National Key Research and Development Program of China (2022YFF1302800) and National Natural Science Foundation of China (32271589, 31870457).

Abstract

Abstract: Atmospheric nitrogen (N) deposition is anticipated to stabilize or decline in numerous global regions. However, the residual effects of historical N enrichment on soil microbial communities—particularly their regulatory mechanisms—remain poorly understood. Our 18-year grassland experiment indicated that bacterial communities in bulk soil exhibited greater sensitivity to N addition compared to those in rhizosphere soil, suggesting host plants affect the response of soil bacteria to N enrichment. Following cessation of N addition, there was limited bacterial community recovery, especially in the rhizosphere soil of forb species. Although root exudates from plants underwent significant alterations under N enrichment, the sensitivity of bacterial communities was primarily governed by changes in soil properties and root traits. In contrast to host selection, environmental filtering factors, particularly soil pH and metal ions, mainly determined the resilience of the overall community by differentially affecting bacterial groups with distinct life-history strategies. Oligotrophic bacteria were negatively impacted by reduced pH and elevated metal ion levels, leading to a decline following N enrichment. Conversely, copiotrophic bacteria initially benefited from metal ions, exhibiting an increase followed by a decrease after the addition and subsequent cessation of N enrichment. These findings indicate that soil environmental filtration exerts a more substantial influence than host selection on bacterial communities in response to N disturbances, thereby enhancing our understanding of the mechanisms underlying plant–microbial interactions under ongoing global changes.

Key words: nitrogen addition, cessation of N addition, bacteria, life-history strategies, plant–microbial interactions, soil chemistry, root exudates, root traits

摘要：
减排政策导致全球大部分区域大气氮沉降速率趋于饱和或降低。然而，长期氮富集对土壤微生物群落的遗留效应及其调控机制尚不清楚。基于18年温带草原氮添加模拟实验的结果表明，与植物根际土壤相比，非根际土壤细菌群落对氮富集表现出更高的敏感性。短期停止氮添加对植物根际土壤——特别是杂类草的根际土壤——细菌群落的恢复作用有限。尽管氮富集条件下植物根系分泌物发生显著变化，但是细菌群落的敏感性主要受根际土壤化学性质和根系性状的影响。环境过滤(尤其是土壤pH值和金属离子)对不同生活史策略的细菌类群产生差异化影响：寡营养型细菌在氮富集后减少，这主要与土壤pH值降低和金属离子浓度升高有关；而富营养型细菌则从金属离子中短期获益，呈现先增加后下降的趋势。上述结果表明，土壤环境过滤对细菌群落的影响大于宿主选择作用，这一发现对于深入认识全球变化背景下植物-土壤微生物互作机制具有重要意义。

关键词: 氮添加, 停止施氮, 细菌, 生活史策略, 植物-微生物互作, 土壤化学性质, 根系分泌物, 根系性状

Fangling Ma, Yao Zheng, La Wei, Lin Xiang, Lifei Ren, Wenming Bai, Qiuying Tian, Wen-Hao Zhang. Soil chemistry exerts a more significant influence on bacterial responses to nitrogen disturbances than root exudates[J]. J Plant Ecol, 2025, 18(6): 1-37.

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Soil chemistry exerts a more significant influence on bacterial responses to nitrogen disturbances than root exudates

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