Biosolids amendment effects on nitrogen cycling gene expression by the soil prokaryotic community as revealed by metatranscriptomic analysis

IF 1.2 4区农林科学 Q4 SOIL SCIENCE

Soil Research Pub Date : 2023-01-01 DOI:10.1071/sr23157

Elisa Marie D’Angelo

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引用次数: 0

Abstract

Context Large quantities of treated sewage sludge (biosolids) are produced and beneficially applied to agricultural fields to improve soil fertility in many countries. Biosolids have extremely high concentrations of ammonium and organic matter that can be beneficial but also detrimental to the environment by promoting microbially-mediated reactions that contribute to eutrophication and greenhouse gas emission.Aims The hypothesis of the study was that high concentrations of ammonium and labile organic matter in biosolids would significantly affect nitrogen transformations and nitrogen-cycling gene expression by different members of the prokaryotic community in a biosolids-amended agricultural soil.Methods An organically-managed agricultural soil was amended with biosolids and monitored for changes in carbon dioxide and inorganic nitrogen species for 3weeks under laboratory conditions. Then, RNA was extracted and compared for nitrogen-cycling gene expression levels in biosolids-amended and unamended soil.Key results Biosolids amendment significantly increased ammonium concentration and decreased oxygen and nitrate concentrations in soil zones near biosolid particles, which coincided with significant changes in expression levels of genes for catabolic glutamate dehydrogenase, nitrification enzymes, denitrifying enzymes, and numerous other enzymes by different members of the prokaryotic community.Conclusions The application of biosolids to soil set in motion a dynamic organic nitrogen mineralisation–nitrification–denitrification cycle between the anaerobic biosolids zone and aerobic soil zone.Implications Biosolids-induced changes in nitrogen transformations by different members of the microbial community have implications on nitrogen availability/toxicity to nitrifying populations and plants, ammonium and nitrate in surface runoff, and nitrous oxide greenhouse gas emission from biosolids-amended soil.

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元转录组学分析揭示生物固体对土壤原核生物群落氮循环基因表达的影响

许多国家生产了大量经过处理的污水污泥(生物固体)，并将其有效地应用于农田，以提高土壤肥力。生物固体具有极高浓度的铵和有机物，通过促进微生物介导的反应促进富营养化和温室气体排放，对环境有益但也有害。本研究假设生物固体中高浓度的铵和活性有机物会显著影响生物固体改良农业土壤中不同原核生物群落成员的氮转化和氮循环基因表达。方法在实验室条件下，用生物固体对农业土壤进行3周的改良，监测土壤中二氧化碳和无机氮的变化。然后，提取RNA，比较生物固体改性和未改性土壤中氮循环基因的表达水平。生物固体改性显著提高了生物固体颗粒附近土壤带的铵态氮浓度，降低了氧和硝酸盐浓度，这与原核生物群落不同成员分解代谢谷氨酸脱氢酶、硝化酶、反硝化酶和许多其他酶的基因表达水平的显著变化相一致。结论生物固体在土壤中的应用启动了厌氧区和好氧区有机氮矿化-硝化-反硝化的动态循环。生物固体引起的不同微生物群落成员氮转化的变化对氮的有效性/对硝化种群和植物的毒性、地表径流中的铵态氮和硝态氮以及生物固体修正土壤的氧化亚氮温室气体排放具有重要影响。

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来源期刊

Soil Research SOIL SCIENCE-

CiteScore

3.20

自引率

6.20%

发文量

审稿时长

4.5 months

期刊介绍： Soil Research (formerly known as Australian Journal of Soil Research) is an international journal that aims to rapidly publish high-quality, novel research about fundamental and applied aspects of soil science. As well as publishing in traditional aspects of soil biology, soil physics and soil chemistry across terrestrial ecosystems, the journal welcomes manuscripts dealing with wider interactions of soils with the environment. Soil Research is published with the endorsement of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Academy of Science.