Periphyton improves soil conditions and offers a suitable environment for rice growth in coastal saline alkali soil

Periphyton plays an indispensable role in coastal saline‐alkali land, but its function is poorly understood. Soil physical and chemical properties (pH value, salinity, soil organic matter), enzyme activity, and microbial diversity (based on 16 s rDNA, ITS and functional genes) were measured in perip...

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Bibliographic Details
Published in:Land degradation & development 2021-05, Vol.32 (9), p.2775-2788
Main Authors: Zhu, Ye, Shao, Tianyun, Zhou, Yujie, Zhang, Xun, Gao, Xiumei, Long, Xiaohua, Rengel, Zed
Format: Article
Language:English
Subjects:
Abundance
Catalase
Chemical properties
Community structure
Cyanobacteria
Enzymatic activity
Enzyme activity
Enzymes
Genes
microbial diversity
Microorganisms
Organic matter
Organic soils
paddy ecosystem
Periphyton
pH effects
Plant growth
Relative abundance
Saline soils
saline‐alkali soil
Salinity
Salinity effects
Soil chemistry
Soil conditioners
Soil conditions
Soil improvement
Soil microorganisms
Soil organic matter
Soil pH
Soil properties
Soil salinity
Soil structure
Soils
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Summary:Periphyton plays an indispensable role in coastal saline‐alkali land, but its function is poorly understood. Soil physical and chemical properties (pH value, salinity, soil organic matter), enzyme activity, and microbial diversity (based on 16 s rDNA, ITS and functional genes) were measured in periphyton formed on rice‐growing coastal saline‐alkali soil modified by a new type of soil conditioner. The results showed that the content of organic matter and catalase activity in periphyton were significantly higher than in the unplanted control soil. Soil pH and salinity were decreased in periphyton compared to the unplanted control soil. Based on the relative abundance, bacterial genera Desulfomicrobium, Rhodobacter, cyanobacterium_scsio_T−2, Gemmatimonas, and Salinarimonas as well as fungal genus Fusarium were more abundant in periphyton than the unplanted control soil. In terms of functional genes, the cbbM and cbbL sequencing showed higher abundance of Hydrogenophaga, Rhodovulum, Magnetospira, Leptothrix, and Thiohalorhabdus, whereas the nifH sequencing indicated higher abundance of Cyanobacteria in the periphyton compared to the unplanted soil. The relative abundance and community structure of soil microorganisms were improved by periphyton, thus reducing soil salinity and pH, and increasing soil organic matter and enzyme activity. This indicated that the periphyton can improve the conditions and offer a suitable environment for plant growth in coastal saline‐alkali soil.
ISSN:1085-3278
1099-145X
DOI:10.1002/ldr.3944