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Ecosystem restoration through aerial seeding: Interacting plant–soil microbiome effects on soil multifunctionality

Understanding the driving factors of soil multifunctionality is of great significance for the protection and restoration of degraded terrestrial ecosystems. However, the effects of above‐ and belowground factors are rarely evaluated simultaneously, and the driving mode of both factors on soil multif...

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Bibliographic Details
Published in:Land degradation & development 2021-12, Vol.32 (18), p.5334-5347
Main Authors: Liu, Qingfu, Zhang, Qing, Jarvie, Scott, Yan, Yongzhi, Han, Peng, Liu, Tao, Guo, Kun, Ren, Linjing, Yue, Kai, Wu, Haiming, Du, Jingjing, Niu, Jianming, Svenning, Jens‐Christian
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Language:English
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Summary:Understanding the driving factors of soil multifunctionality is of great significance for the protection and restoration of degraded terrestrial ecosystems. However, the effects of above‐ and belowground factors are rarely evaluated simultaneously, and the driving mode of both factors on soil multifunctionality is not clear. Here, we evaluated the restoration of mobile dunes threatened by desertification through aerial seeding, that is, the sowing of seeds through aerial devices, from 1983 to 2015 in Mu Us Desert, China, using soil and plant data. The effect of aerial seeding on the restoration of soil multifunctionality, plant diversity, and soil microbial diversity in mobile dunes was significant, which was tested by loess regression. Further, the plant diversity becomes saturated in the later stages of restoration. The effect also leads to the restoration of soil multifunctionality lags behind plant and soil microorganisms. The factors (plant and soil microorganisms) driving soil multifunctionality is not a separate action or a joint action that test by structural equation models (SEMs), but that plants restore first and then indirectly drive soil multifunctionality through soil microorganisms during the restoration process. We also found that bacteria are the main direct indicators of soil multifunctionality, which was tested using Random forests modelling. This study highlights that plants indirectly drive soil multifunctionality through soil microorganisms, and soil microorganisms are key to elucidating the restoration mechanism and process.
ISSN:1085-3278
1099-145X
DOI:10.1002/ldr.4112