Response of soil microbial community structure to temperature and nitrogen fertilizer in three different provenances of Pennisetum alopecuroides

Soil microorganisms are key indicators of soil health, and it is crucial to investigate the structure and interactions of soil microbial communities among three different provenances of under varying nitrogen fertilizer and temperature levels in Northwest China. This study aims to provide theoretica...

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Bibliographic Details
Published in:Frontiers in microbiology 2024-10, Vol.15, p.1483150
Main Authors: Deng, Niandong, Nian, Lili, Zhang, Shuolun, Liang, Yixuan, Shang, Huiying, Li, Yang, Mao, Zhuxin
Format: Article
Language:English
Subjects:
ecological networks
Microbiology
nitrogen addition
Pennisetum
soil microbes
temperature
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Summary:Soil microorganisms are key indicators of soil health, and it is crucial to investigate the structure and interactions of soil microbial communities among three different provenances of under varying nitrogen fertilizer and temperature levels in Northwest China. This study aims to provide theoretical support for the sustainable use of artificial grassland in this region. Employing a two-factor pot-control experiment with three nitrogen fertilizer treatments and three temperature treatments, a total of all treatments was utilized to examine the composition and abundance of soil microbial communities associated with using high-throughput sequencing, PCR technology, and molecular ecological network analysis. The results revealed that was the dominant bacterial phylum while was the dominant fungal phylum in the soil samples from three provenances of . Specifically, exhibited higher abundance in the N3T2 treatment compared to other treatments under N3T2 (25-30°C, 3 g/pot) treatment conditions in Shaanxi and Gansu provinces; similarly, was more abundant in the N1T2 (25-30°C, 1 g/pot) treatment in Inner Mongolia under N1T2. Moreover, Ascomycota displayed higher abundance than other treatments in both Inner Mongolia and Gansu provinces. Additionally, demonstrated greater prevalence under (25-30°C, 3 g/pot) treatment compared to other treatments; furthermore, Shaanxi's exhibited increased prevalence under N3T1 (18-23°C, 3 g/pot) treatment compared to other treatments. The richness and diversity of soil microbial communities were significantly influenced by nitrogen fertilizer and temperature changes, leading to notable alterations in their structure. Molecular ecological network analyses revealed strong collaborative relationships among microbial species in Shaanxi and Inner Mongolia under high nitrogen and high temperature treatments, while competitive relationships were observed among microbial species in Gansu under similar conditions. Redundancy analysis indicated that soil pH, total potassium, and total phosphorus were the primary environmental factors influencing microorganisms. In summary, this study offers a theoretical foundation for assessing the sustainable utilization of artificial grasslands in Northwest China by investigating the shifts in soil microbial communities and the driving factors under varying nitrogen fertilizer and temperature levels.
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2024.1483150