Dam construction accelerated the development of biological soil crusts in degraded soil patches in the Lhasa River basin, Qinghai-Tibetan Plateau

The Lhasa River Basin currently faces severe land degradation. In recent years, several dams have been built on the main stream, whereas, their impact on land desertification remains less elucidated. Herein, we investigated variances of soil properties and microbial communities in biological soil cr...

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Published in:Applied soil ecology : a section of Agriculture, ecosystems & environment ecosystems & environment, 2024-08, Vol.200, p.105454, Article 105454
Main Authors: Tao, Yue, Li, Yan, Tu, Jiawei, Chen, Zixu, Fu, Yaojia, Ye, Wenyan, Zhu, Jing, Chen, Chaoqi, Hou, Lianghui, Chen, Lanzhou
Format: Article
Language:English
Subjects:
altitude
Biological soil crusts (BSCs)
China
Cyanobacteria
Dam construction
Degraded soil
desertification
ecological restoration
enzymes
equations
Formation and development
genes
land degradation
Microbial community structure
mosses and liverworts
nitrogen cycle
rivers
soil
soil degradation
soil ecology
soil nutrients
water distribution
watersheds
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Summary:The Lhasa River Basin currently faces severe land degradation. In recent years, several dams have been built on the main stream, whereas, their impact on land desertification remains less elucidated. Herein, we investigated variances of soil properties and microbial communities in biological soil crusts (BSCs) along the valley area of Lhasa River and the mountain slope (altitude gradient) in reservoir area after five years of dam construction. Soil nutrient and water contents, enzyme activities, and N-cycle related functional gene copies significantly increased in reservoir-affected areas and decreased with the increase of mountain slope altitude and the distance away from the reservoir, which were usually degraded soil patches; similarly, the relative abundance of bacteria, fungi and moss in BSCs significantly increased in reservoir-affected areas, whilst that of cyanobacteria was higher in degraded soil patches. The linear and structural equation models also showed that dam construction altered water distribution status of soil surface, which enhanced soil properties, N-cycle and increased the relative abundance of moss of BSCs, and successfully accelerated the development and succession of BSCs in degraded soil. This study firstly reported that dam construction could accelerate the succession process of degraded soil in the reservoir affected area and thus a reference for ecological restoration of desertification soil of the Lhasa River Basin in QTP. [Display omitted] •Investigated variances of soil properties and microbial communities in biological soil crusts (BSCs).•Dam construction affect BSCs development and soil properties significantly.•Soil properties affected by dam construction influence BSCs microbial diversity.
ISSN:0929-1393
1873-0272
DOI:10.1016/j.apsoil.2024.105454