Key Laboratory of Soil Environment and Pollution Remediation, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, People's Republic of China.
Shanghai Majorbio Bio-pharm Biotechnology Co., Ltd., Shanghai, People's Republic of China.
mSystems. 2022 Apr 26;7(2):e0104721. doi: 10.1128/msystems.01047-21. Epub 2022 Mar 1.
Soil microbiota plays fundamental roles in maintaining ecosystem functions and services, including biogeochemical processes and plant productivity. Despite the ubiquity of soil microorganisms from the topsoil to deeper layers, their vertical distribution and contribution to element cycling in subsoils remain poorly understood. Here, nine soil profiles (0 to 135 cm) were collected at the local scale (within 300 km) from two canonical paddy soil types (Fe-accumuli and Hapli stagnic anthrosols), representing redoximorphic and oxidative soil types, respectively. Variations with depth in edaphic characteristics and soil bacterial and diazotrophic community assemblies and their associations with element cycling were explored. The results revealed that nitrogen and iron status were the most distinguishing edaphic characteristics of the two soil types throughout the soil profile. The acidic Fe-accumuli stagnic anthrosols were characterized by lower concentrations of free iron oxides and total iron in topsoil and ammonia in deeper layers compared with the Hapli stagnic anthrosols. The bacterial and diazotrophic community assemblies were mainly shaped by soil depth, followed by soil type. Random forest analysis revealed that nitrogen and iron cycling were strongly correlated in Fe-accumuli stagnic anthrosol, whereas in Hapli soil, available sulfur was the most important variable predicting both nitrogen and iron cycling. The distinctive biogeochemical processes could be explained by the differences in enrichment of microbial taxa between the two soil types. The main discriminant clades were the iron-oxidizing denitrifier , , and diazotrophic taxa (iron-reducing , , and ) in Fe-accumuli stagnic anthrosol and the sulfur-reducing diazotroph in Hapli stagnic anthrosol. Rice paddy ecosystems support nearly half of the global population and harbor remarkably diverse microbiomes and functions in a variety of soil types. Diazotrophs provide significant bioavailable nitrogen in paddy soil, priming nitrogen transformation and other biogeochemical processes. This study provides a novel perspective on the vertical distribution of bacterial and diazotrophic communities in two hydragric anthrosols. Microbiome analysis revealed divergent biogeochemical processes in the two paddy soil types, with a dominance of nitrogen-iron cycling processes in Fe-accumuli stagnic anthrosol and sulfur-nitrogen-iron coupling in Hapli stagnic anthrosol. This study advances our understanding of the multiple significant roles played by soil microorganisms, especially diazotrophs, in biogeochemical element cycles, which have important ecological and biogeochemical ramifications.
土壤微生物在维持生态系统功能和服务方面发挥着基础性作用,包括生物地球化学过程和植物生产力。尽管土壤微生物从表土到深层都普遍存在,但它们在亚土层中的垂直分布及其对元素循环的贡献仍知之甚少。在这里,从两个典型的稻田土壤类型(富铁累积和弱粘淀积潜育土)中,在当地尺度(300km 内)收集了 9 个土壤剖面(0 到 135cm),分别代表氧化还原和氧化土壤类型。研究了土壤特性、土壤细菌和固氮生物群落的垂直分布变化及其与元素循环的关系。结果表明,氮和铁的状态是两种土壤类型在整个土壤剖面中最具区别性的土壤特性。酸性富铁累积潜育土的特点是,与弱粘淀积潜育土相比,表土中游离氧化铁和总铁以及深层土壤中的氨浓度较低。细菌和固氮生物群落的组成主要由土壤深度决定,其次是土壤类型。随机森林分析表明,氮和铁的循环在富铁累积潜育土中紧密相关,而在弱粘淀积土中,可用硫是预测氮和铁循环的最重要变量。两种土壤类型之间微生物类群的富集差异可以解释独特的生物地球化学过程。主要的鉴别类群是富铁累积潜育土中的铁氧化反硝化菌、固氮菌和固氮菌(铁还原菌和固氮菌),而弱粘淀积潜育土中的硫还原固氮菌。水稻稻田生态系统为全球近一半的人口提供支持,在各种土壤类型中拥有极为多样的微生物组和功能。固氮生物为稻田土壤提供了大量可利用的氮,启动了氮转化和其他生物地球化学过程。本研究为两种水耕潜育土中细菌和固氮生物群落的垂直分布提供了新的视角。微生物组分析揭示了两种稻田土壤类型中不同的生物地球化学过程,富铁累积潜育土中以氮-铁循环过程为主,弱粘淀积潜育土中以硫-氮-铁偶联过程为主。本研究增进了我们对土壤微生物,特别是固氮生物在生物地球化学元素循环中所起的多种重要作用的认识,这对生态和生物地球化学具有重要影响。
