Effect of 35 years inorganic fertilizer and manure amendment on structure of bacterial and archaeal communities in black soil of northeast China

•35 years of inorganic fertilizer and manure amendment alter the soil bacterial and archaeal community.•pH and NO3− concentration played important roles in shaping the community structures.•Inorganic fertilizers decrease soil bacterial and archaeal diversity.•The incorporation of inorganic fertilize...

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Published in:Applied soil ecology : a section of Agriculture, ecosystems & environment ecosystems & environment, 2016-09, Vol.105, p.187-195
Main Authors: Ding, Jianli, Jiang, Xin, Ma, Mingchao, Zhou, Baoku, Guan, Dawei, Zhao, Baisuo, Zhou, Jing, Cao, Fengming, Li, Li, Li, Jun
Format: Article
Language:English
Subjects:
Acidobacteria
Actinobacteria
alpha-Proteobacteria
beta-Proteobacteria
biofertilizers
Black soil
community structure
correlation
crop production
delta-Proteobacteria
gamma-Proteobacteria
genes
Inorganic fertilizer
long term effects
Manure amendment
microbial communities
Microbial community structure
mineral fertilizers
nitrate nitrogen
nitrogen
organic fertilizers
phosphorus
potassium
Proteobacteria
quantitative polymerase chain reaction
ribosomal RNA
soil pH
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Summary:•35 years of inorganic fertilizer and manure amendment alter the soil bacterial and archaeal community.•pH and NO3− concentration played important roles in shaping the community structures.•Inorganic fertilizers decrease soil bacterial and archaeal diversity.•The incorporation of inorganic fertilizer and manure increase soil bacterial and archaeal diversity. Black soil is common in northeast China and plays an important role in Chinese crop production. However, in the past three decades, inappropriate use of fertilizer has caused a sequence of agroecological issues. The objective of this research was to evaluate the effect of long-term fertilizer on the microbial communities in black soil. The soil was subjected to four fertilization regimes: without fertilizer (CK); manure (M); nitrogen, phosphorus and potassium inorganic fertilizer (NPK); and inorganic fertilizers with manure (MNPK). The soil pH was decreased by inorganic fertilizers and increased by manure. Quantitative PCR analysis of microbial community size and Illumina platform-based analysis of the V4 16S rRNA gene region were performed to characterize soil microbial abundance and to compare community structure and diversity. Microbial community size was enhanced by the incorporation of inorganic fertilizer and manure. Microbial diversity was decreased by inorganic fertilizer and increased by the incorporation of inorganic fertilizer and manure. The predominate phyla in all samples were Proteobacteria (29.39–33.48%), Acidobacteria (13.14–16.25%) and Actinobacteria (9.32–10.77%). The relative abundance of different classes significantly differed among the different treatments, especially MNPK and NPK. Acidobacteria and Deltaproteobacteria were relatively stable in organic fertilizer treated soil. Gammaproteobacteria, Alphaproteobacteria and Betaproteobacteria were sensitive to all the fertilization regimes. Comparatively, Spartobacteria was stable in response to fertilization practices. Principal coordinate analysis indicated that microbial communities were primarily clustered into three groups: CK and M were clustered together; MNPK was improved by manure and separated from NPK. Shannon and Simpson indexes were significantly correlated with soil pH and the concentrations of available phosphorus and total phosphorus. Redundancy analysis indicates that microbial communities were closely positively correlated with soil nitrate nitrogen concentration (P=0.002) and pH (P=0.002). These results indicate t
ISSN:0929-1393
1873-0272
DOI:10.1016/j.apsoil.2016.04.010