Long-term effects of straw and straw-derived biochar on soil aggregation and fungal community in a rice-wheat rotation system

Soil aggregation is fundamental for soil functioning and agricultural productivity. Aggregate formation depends on microbial activity influencing the production of exudates and hyphae, which in turn act as binding materials. Fungi are also important for improving soil quality and promoting plant gro...

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Bibliographic Details
Published in:PeerJ (San Francisco, CA) CA), 2019-01, Vol.6, p.e6171-e6171, Article e6171
Main Authors: Bai, Naling, Zhang, Hanlin, Li, Shuangxi, Zheng, Xianqing, Zhang, Juanqin, Zhang, Haiyun, Zhou, Sheng, Sun, Huifeng, Lv, Weiguang
Format: Article
Language:English
Subjects:
Agricultural wastes
Agriculture
Biology
Biomass
Biosolids
Carbon dioxide
Carbon sequestration
Community structure
Crop rotation
Double cropping
Ecology
Exudates
Fertilization
Fertilizers
Fungal community structure
Fungi
Hyphae
Illumina sequencing
Loam soils
Long-term effects
Metabolism
Microbiology
Microorganisms
Nitrogen
Organic soils
Oryza
Physicochemical properties
Plant growth
Potassium
Raw materials
Rice
Silt
Soil aggregation
Soil microorganisms
Soil sciences
Spacer
Straw
Straw and biochar
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Summary:Soil aggregation is fundamental for soil functioning and agricultural productivity. Aggregate formation depends on microbial activity influencing the production of exudates and hyphae, which in turn act as binding materials. Fungi are also important for improving soil quality and promoting plant growth in a symbiotic manner. There is a scarcity of findings comparing the long-term impacts of different yearly double-crop straw return modes (e.g., straw return to the field and straw-derived biochar return to the field) on soil aggregation and fungal community structure in rice-wheat rotation systems. The effects of 6-year continuous straw and straw-derived biochar amendment on soil physicochemical properties and the fungal community were evaluated in an intensively managed crop rotation system (rice-wheat). Soil samples of different aggregates (macroaggregates, microaggregates, and silt clay) from four different fertilization regimes (control, CK; traditional inorganic fertilization, CF; straw returned to field, CS; straw-derived biochar addition, CB) were obtained, and Illumina MiSeq sequencing analysis of the fungal internal transcribed spacer gene was performed. Compared to CF, CS and CB enhanced soil organic carbon, total nitrogen, and aggregation in 0-20 and 20-40 cm soil, with CB exhibiting a stronger effect. Additionally, agrowaste addition increased the mean weight diameter and the geometric diameter and decreased the fractal dimension ( < 0.05). Principal coordinates analysis indicated that fertilization management affected fungal community structure and aggregation distribution. In addition, CS increased fungal community richness and diversity, compared to CK, CB decreased these aspects. Ascomycota, unclassified_k_Fungi, and Basidiomycota were the dominant phyla in all soil samples. At the genus level, CB clearly increased fungi decomposing biosolids ( in macroaggregates in 0-20 cm soil and in macroaggregates in 20-40 cm soil); decreased pathogenic fungi ( in macroaggregates and in microaggregates in 0-20 cm soil) and CO -emission-related fungi ( in microaggregates and silt clay in 0-40 cm soil) ( < 0.05). Straw and biochar with inorganic fertilizer counteracted some of the adverse effects of the inorganic fertilizer with biochar showing better effects than straw.
ISSN:2167-8359
2167-8359
DOI:10.7717/peerj.6171