Long-term application of silicate fertilizer alters microbe-mediated phosphorus cycling in paddy soils

• Published in: Agriculture, ecosystems & environment Vol. 374; p. 109175
• Main Authors: Lee, Chang Hoon, Das, Suvendu, Park, Mun Hyeong, Kim, Sang Yoon, Kim, Pil Joo
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 15.10.2024
• Subjects: agriculture; environment; equations; fertilizers; genes; Industrial slag; Metagenome; Microbial functions; mineralization; nonpoint source pollution; P cycling; paddies; phosphorus; Recycling by-product; rice; Silicate; silicates; slags; soil pH; solubilization; starvation; stoichiometry; Industrial slag; P cycling; Recycling by-product; Silicate; Microbial functions; Metagenome
• ISSN: 0167-8809; 1873-2305
• DOI: 10.1016/j.agee.2024.109175

Rice plants require a large amount of phosphorus (P) fertilizer for cultivation. However, much of the P added to soils is fixed and unusable by rice plants. The use of silicate fertilizers to improve P availability to plants has been documented, but the mechanism remains unclear. We studied soil P pools and microbe-regulated P cycling in rice fields after 30-year application of silicate fertilizer (SF) made from blast-furnace slag. Long-term application of SF did not significantly change available P in the soil, but significantly increased P uptake by rice plants due to higher yield. Under long-term SF fertilization compared to no-SF, the abundance of functional genes for organic-P mineralization (phoA, phoB, and phy) and inorganic-P solubilization (ppx, ppk, and gcd) increased, whereas the genes for P uptake and transport systems (pst and pit) and P starvation response (phoB) did not change significantly. Increased microbial P mineralization and solubilization was attributed to the increased P demand by the crop. Structural equation modeling shows that microbial P-transforming gene community was associated with Si availability, soil pH, plant P uptake, and soil C:P and N:P stoichiometry. A significant decrease in Fe-P and an increase in Ca-P pools under Si fertilizer addition indicated their respective roles in P availability and P reserve in the SF treatment. We conclude that long-term application of SF increased P uptake by rice plants by enhancing microbial mobilization of soil P and crop yields, potentially improving recycling of slag while reducing the use of chemical P fertilizers that can lessen environmental risks associated with non-point source pollution. [Display omitted] •Long-term silicate fertilization (SF) improved microbial P cycling in paddy soils.•SF increased microbial gene abundance for P solubilization and mineralization.•Genes involved in P uptake and transport and P starvation did not change by SF.•SF decreased soil Fe-P but increased Ca-P, inorganic P, and organic P.•Microbial P cycling was mainly regulated by soil pH, Si availability, C:P and N:P.