Neal Andrew L, Hughes David, Clark Ian M, Jansson Janet K, Hirsch Penny R
Department of Sustainable Agriculture Science, Rothamsted Research, North Wyke, Devon, United Kingdom.
Department of Computational and Analytical Sciences, Rothamsted Research, Harpenden, Hertfordshire, United Kingdom.
mSystems. 2021 Jun 29;6(3):e0105620. doi: 10.1128/mSystems.01056-20. Epub 2021 May 27.
How soil is managed, particularly for agriculture, exerts stresses upon soil microbiomes, resulting in altered community structures and functional states. Understanding how soil microbiomes respond to combined stresses is important for predicting system performance under different land use scenarios, aids in identification of the most environmentally benign managements, and provides insight into how system function can be recovered in degraded soils. We use a long-established field experiment to study the effects of combined chronic (press) disturbance of the magnitude of organic carbon inputs with acute (pulse) effects of physical disturbance by tillage and chemical disturbance due to inorganic fertilization and pesticide application. We show that because of the variety of ways it can be assessed, biodiversity-here based on microbial small subunit rRNA gene phylotypes-does not provide a consistent view of community change. In contrast, aggregated traits associated with soil microbiomes indicate general loss of function, measured as a reduction of average genome lengths, associated with chronic reduction of organic inputs in arable or bare fallow soils and altered growth strategies associated with rRNA operon copy number in prokaryotes, as well as a switch to pathogenicity in fungal communities. In addition, pulse disturbance by soil tillage is associated with an increased influence of stochastic processes upon prokaryote community assembly, but fungicide used in arable soils results in niche assembly of fungal communities compared to untilled grassland. Overall, bacteria, archaea, and fungi do not share a common response to land management change, and estimates of biodiversity do not capture important facets of community adaptation to stresses adequately. Changes in soil microbiome diversity and function brought about by land management are predicted to influence a range of environmental services provided by soil, including provision of food and clean water. However, opportunities to compare the long-term effects of combinations of stresses imposed by different management approaches are limited. We exploit a globally unique 50-year field experiment, demonstrating that soil management practices alter microbiome diversity, community traits, and assembly. Grassland soil microbiomes are dominated by fewer-but phylogenetically more diverse-prokaryote phylotypes which sustain larger genomes than microbiomes in arable or bare fallow soil maintained free of plants. Dominant fungi in grassland soils are less phylogenetically diverse than those in arable or fallow soils. Soil tillage increases stochastic processes in microbiome assembly: this, combined with reduced plant biomass, presents opportunities for organisms with a capacity for pathogenesis to become established in stressed soils.
土壤的管理方式,尤其是农业土壤管理方式,会对土壤微生物群落施加压力,导致群落结构和功能状态发生改变。了解土壤微生物群落如何应对复合胁迫,对于预测不同土地利用情景下的系统性能、帮助确定最有利于环境的管理方式以及深入了解退化土壤中系统功能如何恢复都很重要。我们利用一项长期的田间试验,研究有机碳输入量的长期(持续性)干扰与耕作造成的物理干扰以及无机肥料和农药施用造成的化学干扰的短期(脉冲式)影响相结合的效应。我们发现,由于生物多样性(这里基于微生物小亚基rRNA基因系统型)的评估方式多种多样,它并不能提供关于群落变化的一致观点。相比之下,与土壤微生物群落相关的综合性状表明功能普遍丧失,表现为平均基因组长度缩短,这与耕地或裸地休耕土壤中有机输入的长期减少以及原核生物中与rRNA操纵子拷贝数相关的生长策略改变有关,同时真菌群落也转向致病性。此外,土壤耕作的脉冲式干扰与随机过程对原核生物群落组装的影响增加有关,但与未耕作的草地相比,耕地中使用的杀真菌剂会导致真菌群落的生态位组装。总体而言,细菌、古菌和真菌对土地管理变化没有共同的反应,生物多样性估计也不能充分捕捉群落对胁迫的重要适应方面。预计土地管理带来的土壤微生物群落多样性和功能变化会影响土壤提供的一系列生态系统服务,包括提供食物和清洁水源。然而,比较不同管理方式施加的复合胁迫长期影响的机会有限。我们利用一项全球独一无二的50年田间试验,证明土壤管理实践会改变微生物群落多样性、群落性状和组装。草地土壤微生物群落由较少但系统发育上更具多样性的原核生物系统型主导,这些系统型维持着比没有植物的耕地或裸地休耕土壤中的微生物群落更大的基因组。草地土壤中的优势真菌在系统发育上的多样性低于耕地或休耕土壤中的真菌。土壤耕作增加了微生物群落组装中的随机过程:这与植物生物量减少相结合,为具有致病能力的生物体在受胁迫土壤中定殖提供了机会。
