Microbes drive global soil nitrogen mineralization and availability

IF 10.8 1区环境科学与生态学 Q1 BIODIVERSITY CONSERVATION

Global Change Biology Pub Date : 2018-12-27 DOI:10.1111/gcb.14557

Zhaolei Li, Dashuan Tian, Bingxue Wang, Jinsong Wang, Song Wang, Han Y. H. Chen, Xiaofeng Xu, Changhui Wang, Nianpeng He, Shuli Niu

{"title":"Microbes drive global soil nitrogen mineralization and availability","authors":"Zhaolei Li, Dashuan Tian, Bingxue Wang, Jinsong Wang, Song Wang, Han Y. H. Chen, Xiaofeng Xu, Changhui Wang, Nianpeng He, Shuli Niu","doi":"10.1111/gcb.14557","DOIUrl":null,"url":null,"abstract":"Soil net nitrogen mineralization rate (Nmin), which is critical for soil nitrogen availability and plant growth, is thought to be primarily controlled by climate and soil physical and/or chemical properties. However, the role of microbes on regulating soil Nmin has not been evaluated on the global scale. By compiling 1565 observational data points of potential net Nmin from 198 published studies across terrestrial ecosystems, we found that Nmin significantly increased with soil microbial biomass, total nitrogen, and mean annual precipitation, but decreased with soil pH. The variation of Nmin was ascribed predominantly to soil microbial biomass on global and biome scales. Mean annual precipitation, soil pH, and total soil nitrogen significantly influenced Nmin through soil microbes. The structural equation models (SEM) showed that soil substrates were the main factors controlling Nmin when microbial biomass was excluded. Microbe became the primary driver when it was included in SEM analysis. SEM with soil microbial biomass improved the Nmin prediction by 19% in comparison with that devoid of soil microbial biomass. The changes in Nmin contributed the most to global soil NH4+-N variations in contrast to climate and soil properties. This study reveals the complex interactions of climate, soil properties, and microbes on Nmin and highlights the importance of soil microbial biomass in determining Nmin and nitrogen availability across the globe. The findings necessitate accurate representation of microbes in Earth system models to better predict nitrogen cycle under global change.","PeriodicalId":175,"journal":{"name":"Global Change Biology","volume":"25 3","pages":"1078-1088"},"PeriodicalIF":10.8000,"publicationDate":"2018-12-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1111/gcb.14557","citationCount":"212","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Global Change Biology","FirstCategoryId":"93","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/gcb.14557","RegionNum":1,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"BIODIVERSITY CONSERVATION","Score":null,"Total":0}

引用次数: 212

Abstract

Soil net nitrogen mineralization rate (N_min), which is critical for soil nitrogen availability and plant growth, is thought to be primarily controlled by climate and soil physical and/or chemical properties. However, the role of microbes on regulating soil N_min has not been evaluated on the global scale. By compiling 1565 observational data points of potential net N_min from 198 published studies across terrestrial ecosystems, we found that N_min significantly increased with soil microbial biomass, total nitrogen, and mean annual precipitation, but decreased with soil pH. The variation of N_min was ascribed predominantly to soil microbial biomass on global and biome scales. Mean annual precipitation, soil pH, and total soil nitrogen significantly influenced N_min through soil microbes. The structural equation models (SEM) showed that soil substrates were the main factors controlling N_min when microbial biomass was excluded. Microbe became the primary driver when it was included in SEM analysis. SEM with soil microbial biomass improved the N_min prediction by 19% in comparison with that devoid of soil microbial biomass. The changes in N_min contributed the most to global soil NH₄⁺-N variations in contrast to climate and soil properties. This study reveals the complex interactions of climate, soil properties, and microbes on N_min and highlights the importance of soil microbial biomass in determining N_min and nitrogen availability across the globe. The findings necessitate accurate representation of microbes in Earth system models to better predict nitrogen cycle under global change.

Abstract Image

查看原文本刊更多论文

微生物驱动全球土壤氮矿化和可用性

土壤净氮矿化率(Nmin)对土壤氮素有效性和植物生长至关重要，主要受气候和土壤理化性质的控制。然而，微生物对土壤Nmin的调节作用尚未在全球范围内得到评价。通过对198篇陆地生态系统已发表研究的1565个潜在净Nmin观测数据进行分析，发现Nmin随土壤微生物量、总氮和年平均降水量的增加而显著增加，但随土壤ph的降低而降低。Nmin的变化主要归因于全球和生物群系尺度上的土壤微生物量。年平均降水量、土壤pH值和土壤全氮通过土壤微生物显著影响Nmin。结构方程模型(SEM)表明，在不考虑微生物生物量的情况下，土壤基质是控制Nmin的主要因素。当纳入SEM分析时，微生物成为主要驱动因素。添加土壤微生物量的SEM比不添加土壤微生物量的SEM提高了19%的Nmin预测值。与气候和土壤性质相比，Nmin的变化对全球土壤NH4+-N变化的贡献最大。这项研究揭示了气候、土壤性质和微生物对Nmin的复杂相互作用，并强调了土壤微生物生物量在决定全球Nmin和氮有效性方面的重要性。这些发现需要在地球系统模型中准确地表示微生物，以便更好地预测全球变化下的氮循环。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Global Change Biology 环境科学-环境科学

CiteScore

21.50

自引率

5.20%

发文量

497

审稿时长

3.3 months

期刊介绍： Global Change Biology is an environmental change journal committed to shaping the future and addressing the world's most pressing challenges, including sustainability, climate change, environmental protection, food and water safety, and global health. Dedicated to fostering a profound understanding of the impacts of global change on biological systems and offering innovative solutions, the journal publishes a diverse range of content, including primary research articles, technical advances, research reviews, reports, opinions, perspectives, commentaries, and letters. Starting with the 2024 volume, Global Change Biology will transition to an online-only format, enhancing accessibility and contributing to the evolution of scholarly communication.