Phosphate-cycling activity of the soil microbiome in response to the recycled phosphates struvite and vivianite

Lena Faller; George A. Kowalchuk; Eiko E. Kuramae

doi:10.1016/j.apsoil.2025.106296

Phosphate-cycling activity of the soil microbiome in response to the recycled phosphates struvite and vivianite

Lena Faller, George A. Kowalchuk, Eiko E. Kuramae^* (Corresponding author)

^*Corresponding author for this work

NIOO - Microbial Ecology (ME)

Utrecht University

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

2 Citations (Scopus)

Abstract

Recycling phosphorus from waste streams is crucial for meeting rising fertilizer demands without depleting finite resources. Struvite and vivianite, recovered from wastewater treatment processes, have demonstrated potential as fertilizers. However, the impacts of these recycled phosphates on soil microbial communities, particularly those involved in phosphate cycling and their potential to solubilize struvite and vivianite, are poorly understood. This study examined the effects of struvite and vivianite amendments on soil microbial community composition and activity across diverse management regimes using soil incubation. The microbial community was assessed by 16S rRNA gene and ITS amplicon sequencing, and the phosphate-cycling capacity of the soil microbial communities was assessed via phosphatase activity and solubilization assays targeting inorganic phosphates, including tricalcium phosphate, struvite and vivianite. While the overall composition of the soil microbial community remained largely unchanged following recycled phosphate amendment, specific microbial taxa were enriched, reflecting the chemical properties of the amendments. Struvite application resulted in the enrichment of Nitrosospira and Nitrospira populations, while vivianite amendment favored Streptomyces and Mortierella. Despite these taxa-specific enrichments, all phosphate-cycling activity remained stable following vivianite amendment across all soil management types. Struvite amended soils exhibited a soil-specific dip in phosphate solubilization activity at the beginning of the experiment, but all phosphate-cycling activities were unchanged at the end of the soil incubation. These findings indicate that, independently of soil management regime, struvite and vivianite amendments maintain stable phosphate-cycling activity within soil microbial communities.

Original language	English
Article number	106296
Journal	Applied Soil Ecology
Volume	213
DOIs	https://doi.org/10.1016/j.apsoil.2025.106296
Publication status	Published - Sept 2025

Keywords

Inorganic phosphate solubilization
Microbial phosphate cycling
Organic phosphate mineralization
Phosphate-solubilizing microbes
Recycled phosphate fertilizer
Soil microbial community

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title = "Phosphate-cycling activity of the soil microbiome in response to the recycled phosphates struvite and vivianite",

abstract = "Recycling phosphorus from waste streams is crucial for meeting rising fertilizer demands without depleting finite resources. Struvite and vivianite, recovered from wastewater treatment processes, have demonstrated potential as fertilizers. However, the impacts of these recycled phosphates on soil microbial communities, particularly those involved in phosphate cycling and their potential to solubilize struvite and vivianite, are poorly understood. This study examined the effects of struvite and vivianite amendments on soil microbial community composition and activity across diverse management regimes using soil incubation. The microbial community was assessed by 16S rRNA gene and ITS amplicon sequencing, and the phosphate-cycling capacity of the soil microbial communities was assessed via phosphatase activity and solubilization assays targeting inorganic phosphates, including tricalcium phosphate, struvite and vivianite. While the overall composition of the soil microbial community remained largely unchanged following recycled phosphate amendment, specific microbial taxa were enriched, reflecting the chemical properties of the amendments. Struvite application resulted in the enrichment of Nitrosospira and Nitrospira populations, while vivianite amendment favored Streptomyces and Mortierella. Despite these taxa-specific enrichments, all phosphate-cycling activity remained stable following vivianite amendment across all soil management types. Struvite amended soils exhibited a soil-specific dip in phosphate solubilization activity at the beginning of the experiment, but all phosphate-cycling activities were unchanged at the end of the soil incubation. These findings indicate that, independently of soil management regime, struvite and vivianite amendments maintain stable phosphate-cycling activity within soil microbial communities.",

keywords = "Inorganic phosphate solubilization, Microbial phosphate cycling, Organic phosphate mineralization, Phosphate-solubilizing microbes, Recycled phosphate fertilizer, Soil microbial community",

author = "Lena Faller and Kowalchuk, {George A.} and Kuramae, {Eiko E.}",

note = "Publisher Copyright: {\textcopyright} 2025",

year = "2025",

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doi = "10.1016/j.apsoil.2025.106296",

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AU - Faller, Lena

AU - Kowalchuk, George A.

AU - Kuramae, Eiko E.

PY - 2025/9

Y1 - 2025/9

N2 - Recycling phosphorus from waste streams is crucial for meeting rising fertilizer demands without depleting finite resources. Struvite and vivianite, recovered from wastewater treatment processes, have demonstrated potential as fertilizers. However, the impacts of these recycled phosphates on soil microbial communities, particularly those involved in phosphate cycling and their potential to solubilize struvite and vivianite, are poorly understood. This study examined the effects of struvite and vivianite amendments on soil microbial community composition and activity across diverse management regimes using soil incubation. The microbial community was assessed by 16S rRNA gene and ITS amplicon sequencing, and the phosphate-cycling capacity of the soil microbial communities was assessed via phosphatase activity and solubilization assays targeting inorganic phosphates, including tricalcium phosphate, struvite and vivianite. While the overall composition of the soil microbial community remained largely unchanged following recycled phosphate amendment, specific microbial taxa were enriched, reflecting the chemical properties of the amendments. Struvite application resulted in the enrichment of Nitrosospira and Nitrospira populations, while vivianite amendment favored Streptomyces and Mortierella. Despite these taxa-specific enrichments, all phosphate-cycling activity remained stable following vivianite amendment across all soil management types. Struvite amended soils exhibited a soil-specific dip in phosphate solubilization activity at the beginning of the experiment, but all phosphate-cycling activities were unchanged at the end of the soil incubation. These findings indicate that, independently of soil management regime, struvite and vivianite amendments maintain stable phosphate-cycling activity within soil microbial communities.

AB - Recycling phosphorus from waste streams is crucial for meeting rising fertilizer demands without depleting finite resources. Struvite and vivianite, recovered from wastewater treatment processes, have demonstrated potential as fertilizers. However, the impacts of these recycled phosphates on soil microbial communities, particularly those involved in phosphate cycling and their potential to solubilize struvite and vivianite, are poorly understood. This study examined the effects of struvite and vivianite amendments on soil microbial community composition and activity across diverse management regimes using soil incubation. The microbial community was assessed by 16S rRNA gene and ITS amplicon sequencing, and the phosphate-cycling capacity of the soil microbial communities was assessed via phosphatase activity and solubilization assays targeting inorganic phosphates, including tricalcium phosphate, struvite and vivianite. While the overall composition of the soil microbial community remained largely unchanged following recycled phosphate amendment, specific microbial taxa were enriched, reflecting the chemical properties of the amendments. Struvite application resulted in the enrichment of Nitrosospira and Nitrospira populations, while vivianite amendment favored Streptomyces and Mortierella. Despite these taxa-specific enrichments, all phosphate-cycling activity remained stable following vivianite amendment across all soil management types. Struvite amended soils exhibited a soil-specific dip in phosphate solubilization activity at the beginning of the experiment, but all phosphate-cycling activities were unchanged at the end of the soil incubation. These findings indicate that, independently of soil management regime, struvite and vivianite amendments maintain stable phosphate-cycling activity within soil microbial communities.

KW - Inorganic phosphate solubilization

KW - Microbial phosphate cycling

KW - Organic phosphate mineralization

KW - Phosphate-solubilizing microbes

KW - Recycled phosphate fertilizer

KW - Soil microbial community

U2 - 10.1016/j.apsoil.2025.106296

DO - 10.1016/j.apsoil.2025.106296

M3 - Article

AN - SCOPUS:105009437941

SN - 0929-1393

VL - 213

JO - Applied Soil Ecology

JF - Applied Soil Ecology

M1 - 106296

ER -

Phosphate-cycling activity of the soil microbiome in response to the recycled phosphates struvite and vivianite

Abstract

Keywords

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