模拟土壤侵蚀主要影响油菜根瘤菌层中真菌的数量

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Julian Ruggaber , Ayten Pehlivan , Rainer Remus , Davide Francioli , Stephan Wirth , Jürgen Augustin , Steffen Kolb
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引用次数: 0

摘要

侵蚀的农业土壤会降低土壤有机碳(SOC)含量,从而影响根瘤菌圈中植物与微生物群的相互作用。我们用油菜(Brassica napus L.)进行了一项盆栽实验,探讨了模拟侵蚀对主要微生物群的影响。实验通过从底土(Bt)到表土(Ap)材料的混合(0%、12%、24%)模拟了侵蚀梯度。在三个生长阶段用 14CO2 对油菜植株进行脉冲标记,并对两个土壤分区(块状土壤和根圈土壤)进行采样。根圈土壤中真菌 ITS 拷贝数一直较高,并随着植物生长阶段的增加而降低。细菌 16S rRNA 基因拷贝数只有在开花时才会在根圈出现明显增加。根据开花期真菌与细菌和真菌与古细菌的比例,可以检测到真菌丰度对底土混合物的反应。古细菌既不受土壤分区的影响,也不受底土掺合物的影响。微生物生物量的 14C 活性是土壤微生物组中新同化碳相对输入量的指标,它受生长阶段和区系的影响,并随着生长阶段的延长而降低。在莲座生长阶段,侵蚀土壤根圈中微生物生物质的 14C 活性升高,表明植物对侵蚀因素做出了反应。我们的实验揭示了真菌群落沿着模拟侵蚀梯度的组成分离,以及开花时两种不同土壤区系的真菌选择。开花时,根瘤菌圈中富集了寡球根菌、镰刀菌和根瘤菌以及假定的病原体。由于生态适应性和形态特征(即菌丝可以绕过养分供应不足的土壤区域),真菌可能在强侵蚀和养分稀释土壤的根圈中具有竞争优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulated soil erosion predominantly affects fungal abundance in the rapeseed rhizosphere

Eroded agricultural soils have reduced soil organic carbon (SOC) levels that may affect the plant-microbiome interactions in the rhizosphere. We explored the impact of simulated erosion on major microbial groups in a pot experiment with rapeseed (Brassica napus L.) grown on arable soil with the potential to capture SOC. An erosion gradient was simulated by admixture (0%, 12%, 24%) of subsoil horizon (Bt) to topsoil (Ap) material. Rapeseed plants were pulse-labeled with 14CO2 at three growth stages and two soil compartments (bulk and rhizosphere soil) were sampled. Fungal ITS copy numbers were consistently higher in the rhizosphere and decreased with progressing plant growth stages. A significant increase of bacterial 16S rRNA gene copies in the rhizosphere only occurred at flowering. A response of fungal abundance to subsoil admixture was found detectable based on fungi:Bacteria and fungi:Archaea ratio at flowering. Archaea were neither affected by soil compartment nor subsoil admixture. 14C activity of microbial biomass, an indicator for relative input of freshly assimilated C into soil microbiome, was impacted by growth stage and compartment and decreased with ongoing growth stage. During the rosette growth stage, the 14C activity of the microbial biomass was elevated in the rhizosphere of the eroded soil indicating a plant response to the erosion factor. Our experiment revealed a compositional separation of the fungal community along the simulated erosion gradient and a selection of fungi for the two different soil compartments at flowering. Olpidimycetes, Fusarium and Rhizopus and putative pathogens were enriched in the rhizosphere at flowering. Fungi may have a competitive advantage in the rhizosphere of strongly eroded and nutrient diluted soils due to ecological adaptation and morphological traits i.e. hyphae that can bypass soil areas with low nutrient availability.

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CiteScore
7.20
自引率
4.30%
发文量
567
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