Role of microbial communities in conferring resistance and resilience of soil carbon and nitrogen cycling following contrasting stresses

Shu Xin; Daniell Tim J.; Hallett Paul D.; Baggs Elizabeth M.; Mitchell Susan; Langarica-Fuentes Adrian; Griffiths Bryan S.

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Role of microbial communities in conferring resistance and resilience of soil carbon and nitrogen cycling following contrasting stresses

机译：微生物社区在对比度应力下赋予土壤碳和氮循环的抵抗力和恢复性的作用

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Soils frequently experience environmental stresses that may have transient or persistent impact on important ecosystem services, such as carbon (C) and nitrogen (N) cycling. Microbial communities underpin resistance (the ability to withstand a stress) and resilience (the ability to recover from a stress) of these functions. Whilst functional stability and resilience have been studied extensively, the link to genetic stability is missing. In this study, the resistance and resilience of C mineralization, ammonia oxidation and denitrification, their associated gene abundances (16S rRNA, bacterial amoA, nirK, nirS, nosZ-I and nosZ-II) and bacterial community structures (T-RFLP 16S rRNA) were compared in two managed soils for 28 days after stressing the soils with either a persistent (1 mg Cu soil g(-1)) or a transient (heat at 40 degrees C for 16 h) stress. The average resistance of C mineralization to Cu was 60%, which was significantly greater than the resistance of ammonia oxidation (25%) and denitrification (31%) to Cu. Similarly, the average resilience of C mineralization to Cu was 52%, which was significantly greater than the resilience of ammonia oxidation (12%) and denitrification (18%) to Cu. However, this pattern was not significant after heat stress, indicating the critical role of different stressors. Changes in total bacterial community structure rather than abundance of 16S rRNA reflected the responses of C mineralization to Cu and heat. Both Cu and heat significantly decreased functional gene abundance (amoA, nirK, nirS, nosZ-I and nosZ-II), however, a significant recovery of denitrifying gene abundance was observed after 28 days following heat. There were lack of constant relationships between functional and genetic stability, highlighting that soil physiochemical properties, the nature of the stressor, and microbial life history traits combine to confer functional resistance and resilience. Genetic responses on their own are therefore inadequate in predicating changes to soil functions following stresses.

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来源
《European Journal of Soil Biology》 |2021年第1期|共10页
作者
Shu Xin; Daniell Tim J.; Hallett Paul D.; Baggs Elizabeth M.; Mitchell Susan; Langarica-Fuentes Adrian; Griffiths Bryan S.;
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作者单位

SRUC Crop &

Soil Syst Res Grp West Mains Rd Edinburgh EH9 3JG Midlothian Scotland;

Univ Sheffield Dept Anim &

Plant Sci Sheffield S10 2TN S Yorkshire England;

Univ Aberdeen Sch Biol Sci Aberdeen AB24 3UU Scotland;

Univ Edinburgh Global Acad Agr &

Food Secur Royal Dick Sch Vet Studies Edinburgh EH25 9RG Midlothian Scotland;

James Hutton Inst Ecol Sci Dundee DD2 5DA Scotland;

Eberhard Karls Univ Tubingen Dept Geosci Microbial Ecol Schnarrenbergstr 94-96 D-72076 Tubingen Germany;

SRUC Crop &

Soil Syst Res Grp West Mains Rd Edinburgh EH9 3JG Midlothian Scotland;

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原文格式 PDF
正文语种 eng
中图分类土壤生物学;
关键词
Microbial community; Mineralization; Denitrification; Ammonia oxidation; Stresses; Sustainability;

机译：微生物群落;矿化;反硝化;氨氧化;应力;可持续性;

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Role of microbial communities in conferring resistance and resilience of soil carbon and nitrogen cycling following contrasting stresses

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