Soil legacy of arbuscular mycorrhizal fungus Gigaspora margarita: The potassium-sequestering glomalin improves peanut (Arachis hypogaea) drought resistance and pod yield

•Peanuts cultivated in the sterilized soil with AM fungi-inoculated history exhibit enhanced drought performance.•Potassium-sequestering glomalin directly contributes to the enhanced peanut drought performance.•Peanut root exudates prime the dissociation of glomalin-bound potassium. In agroecosystem...

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Bibliographic Details
Published in:Microbiological research 2021-08, Vol.249, p.126774-126774, Article 126774
Main Authors: Xu, Fang-Ji, Zhang, Ai-Yue, Yu, Ying-Ying, Sun, Kai, Tang, Meng-Jun, Zhang, Wei, Xie, Xing-Guang, Dai, Chuan-Chao
Format: Article
Language:English
Subjects:
Arbuscular mycorrhizal fungi
Drought
Glomalin
Peanut
Potassium
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Summary:•Peanuts cultivated in the sterilized soil with AM fungi-inoculated history exhibit enhanced drought performance.•Potassium-sequestering glomalin directly contributes to the enhanced peanut drought performance.•Peanut root exudates prime the dissociation of glomalin-bound potassium. In agroecosystems, drought stress severely threatens crops development. Although potassium (K) is required in amounts by crops under drought stress, the mobilization and availablity of K are limited by the soil water status. Arbuscular mycorrhizal (AM) fungi can form mutualistic associations with most crops and play direct or indirect roles in the host drought resistance. Considering that the glomalin generated by living AM fungal hyphae can sequester multiple minerals, however, the function of mineral-sequestering glomalin in the crop drought resistance remains unclear. In this study, peanuts cultivated in the sterilized soil with a history of AM fungi inoculation showed significantly enhanced leaf K accumulation, drought resistance and pod yield under drought stress. Through the collection of different types of mineral-sequestering glomalin from living AM fungal hyphae, the peanut drought resistance was improved only when K-sequestering glomalin was added. Moreover, we found that peanut root exudates could prime the dissociation of glomalin-bound K and further satisfy the K requirement of crops. Our study is the first report that K-sequestering glomalin could improve drought performance and peanut pod yield, and it helps us to understand the ecological importance of improving AM symbiosis to face agricultural challenges.
ISSN:0944-5013
1618-0623
DOI:10.1016/j.micres.2021.126774