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Unraveling the diversity dynamics and network stability of alkaline phosphomonoesterase‐producing bacteria in modulating maize yield

Lijun Chen, Guofan Zhu, Alberto Pascual‐García, Francisco Dini‐Andreote, Jie Zheng, Xiaoyue Wang, Shungui Zhou, Yuji Jiang

2024iMeta14 citationsDOIOpen Access PDF

Abstract

Phosphorus, as a nonrenewable resource, plays a crucial role in crop development and productivity. However, the extent to which straw amendments contribute to the dynamics of soil alkaline phosphomonoesterase (ALP)-producing bacterial community and functionality over an extended period remains elusive. Here, we conducted a 7-year long-term field experiment consisting of a no-fertilizer control, a chemical fertilizer treatment, and three straw (straw, straw combined with manure, and straw biochar) treatments. Our results indicated that straw amendments significantly improved the succession patterns of the ALP-producing bacterial diversity. Simultaneously, straw amendments significantly increased the network stability of the ALP-producing bacteria over time, as evidenced by higher network robustness, a higher ratio of negative to positive cohesion, and lower network vulnerability. High dynamic and stability of ALP-producing bacterial community generated high ALP activity which further increased soil Phosphorus (P) availability as well as maize productivity.

Topics & Concepts

Yield (engineering)PhosphomonoesteraseBacteriaStability (learning theory)Diversity (politics)ChemistryBiological systemBiologyComputer scienceBiochemistryPhosphatasePhysicsEnzymeSociologyThermodynamicsGeneticsMachine learningAnthropologyLegume Nitrogen Fixing Symbiosis
Unraveling the diversity dynamics and network stability of alkaline phosphomonoesterase‐producing bacteria in modulating maize yield | Litcius