Department of Microbiology and Plant Biology, University of Oklahomagrid.266900.b, Norman, Oklahoma, USA.
Institute for Environmental Genomics, University of Oklahomagrid.266900.b, Norman, Oklahoma, USA.
mBio. 2022 Jun 28;13(3):e0382921. doi: 10.1128/mbio.03829-21. Epub 2022 Apr 14.
Land conversion for intensive agriculture produces unfavorable changes to soil ecosystems, causing global concern. Soil bacterial communities mediate essential terrestrial ecosystem processes, making it imperative to understand their responses to agricultural perturbations. Here, we used high-throughput sequencing coupled with a functional gene array to study temporal dynamics of soil bacterial communities over 1 year under different disturbance intensities across a U.S. Southern Plains agroecosystem, including tallgrass prairie, Old World bluestem pasture, no-tillage (NT) canola, and conventional tillage (CT) wheat. Land use had the greatest impact on bacterial taxonomic diversity, whereas sampling time and its interaction with land use were central to functional diversity differences. The main drivers of taxonomic diversity were tillage > sampling time > temperature, while all measured factors explained similar amounts of variations in functional diversity. Temporal differences had the strongest correlation with total nitrogen > rainfall > nitrate. Within land uses, community variations for CT wheat were attributed to nitrogen levels, whereas soil organic matter and soil water content explained community variations for NT canola. In comparison, all measured factors contributed almost equally to variations in grassland bacterial communities. Finally, functional diversity had a stronger relationship with taxonomic diversity for CT wheat compared to phylogenetic diversity in the prairie. These findings reinforce that tillage management has the greatest impact on bacterial community diversity, with sampling time also critical. Hence, our study highlights the importance of the interaction between temporal dynamics and land use in influencing soil microbiomes, providing support for reducing agricultural disturbance to conserve soil biodiversity. Agricultural sustainability relies on healthy soils and microbial diversity. Agricultural management alters soil conditions and further influences the temporal dynamics of soil microbial communities essential to ecosystem functions, including organic matter dynamics, nutrient cycling, and plant nutrient availability. Yet, the responses to agricultural management are also dependent on soil type and climatic region, emphasizing the importance of assessing sustainability at local scales. To evaluate the impact of agricultural management practices, we examined bacterial communities across a management disturbance gradient over 1 year in a U.S. Southern Plains agroecosystem and determined that intensive management disturbance and sampling time critically impacted bacterial structural diversity, while their interactive effect influenced functional diversity and other soil health indicators. Overall, this study provides insights into how reducing soil disturbance can positively impact microbial community diversity and soil properties in the U.S. Southern Plains.
土地转为集约化农业会对土壤生态系统产生不利变化,引起全球关注。土壤细菌群落介导着重要的陆地生态系统过程,因此必须了解它们对农业干扰的响应。在这里,我们使用高通量测序结合功能基因芯片,研究了美国南部平原农业生态系统中不同干扰强度下土壤细菌群落在 1 年内的时间动态,包括高草草原、旧世界蓝草牧场、免耕(NT)油菜和常规耕作(CT)小麦。土地利用对细菌分类多样性的影响最大,而采样时间及其与土地利用的相互作用是功能多样性差异的中心。分类多样性的主要驱动因素是耕作>采样时间>温度,而所有测量的因素都解释了功能多样性变化的相似量。时间差异与总氮>降雨>硝酸盐的相关性最强。在土地利用中,CT 小麦的群落变化归因于氮水平,而 NT 油菜的群落变化则归因于土壤有机质和土壤含水量。相比之下,土地利用中的所有测量因素几乎都对草原细菌群落的变化有贡献。最后,与 prairie 的系统发育多样性相比,功能多样性与 CT 小麦的分类多样性有更强的关系。这些发现强化了耕作管理对细菌群落多样性的影响最大,采样时间也很关键。因此,我们的研究强调了时间动态和土地利用之间相互作用对土壤微生物组的重要性,为减少农业干扰以保护土壤生物多样性提供了支持。农业可持续性依赖于健康的土壤和微生物多样性。农业管理改变了土壤条件,并进一步影响了对生态系统功能至关重要的土壤微生物群落的时间动态,包括有机质动态、养分循环和植物养分供应。然而,对农业管理的响应也取决于土壤类型和气候区,这强调了在当地尺度评估可持续性的重要性。为了评估农业管理实践的影响,我们在美国南部平原农业生态系统中考察了 1 年内管理干扰梯度上的细菌群落,并确定集约化管理干扰和采样时间对细菌结构多样性有重要影响,而它们的相互作用则影响了功能多样性和其他土壤健康指标。总的来说,这项研究提供了关于如何减少土壤干扰可以积极影响美国南部平原微生物群落多样性和土壤特性的见解。
