Effects of long-term phosphorus addition on soil ratios of phosphomonoesterase to phosphodiesterase in three tropical forests

Taiki Mori; Senhao Wang; Cong Wang; Ji Chen; Cheng Peng; Mianhai Zheng; Juan Huang; Faming Wang; Zhanfeng Liu; Jiangming Mo; Wei Zhang

doi:10.1093/jpe/rtac091

Effects of long-term phosphorus addition on soil ratios of phosphomonoesterase to phosphodiesterase in three tropical forests

Taiki Mori, Senhao Wang, Cong Wang, Ji Chen, Cheng Peng, Mianhai Zheng, Juan Huang, Faming Wang, Zhanfeng Liu, Jiangming Mo, Wei Zhang^*

^*Corresponding author af dette arbejde

Publikation: Bidrag til tidsskrift/Konferencebidrag i tidsskrift /Bidrag til avis › Tidsskriftartikel › Forskning › peer review

2 Citationer (Scopus)

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Abstract

Soil microorganisms in tropical forests can adapt to phosphorus (P)-poor conditions by changing the activity ratios of different types of phosphatases. We tested whether microorganisms in P-poor tropical forest soils increased the phosphomonoesterase (PME) to phosphodiesterase (PDE) activity ratio, because a one-step enzymatic reaction of monoester P degradation might be more adaptive for microbial P acquisition than a two-step reaction of diester P degradation. A continuous 10-year P addition experiment was performed in three tropical forests. The activities of PME and PDE, and their ratio in soil, were determined under the hypothesis that the P-fertilized plots where P shortage is relieved would have lower PME:PDE ratios than the unfertilized controls. We demonstrated that long-term P addition in tropical forest soil did not alter the PME:PDE ratio in primary and secondary forests, whereas P fertilization elevated the PME:PDE ratio in planted forest. These results were in contrast to previous results. The long-term, large-scale P fertilization in our study may have reduced litter- and/or throughfall-derived PDE, which negated the lowered PME:PDE ratio via exogenous P inputs.

Originalsprog	Engelsk
Artikelnummer	rtac091
Tidsskrift	Journal of Plant Ecology
Vol/bind	16
Nummer	3
Antal sider	5
ISSN	1752-9921
DOI	https://doi.org/10.1093/jpe/rtac091
Status	Udgivet - jun. 2023

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10.1093/jpe/rtac091Licens: CC BY-NC

rtac091Forlagets udgivne version, 391 KBLicens: CC BY-NC

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title = "Effects of long-term phosphorus addition on soil ratios of phosphomonoesterase to phosphodiesterase in three tropical forests",

abstract = "Soil microorganisms in tropical forests can adapt to phosphorus (P)-poor conditions by changing the activity ratios of different types of phosphatases. We tested whether microorganisms in P-poor tropical forest soils increased the phosphomonoesterase (PME) to phosphodiesterase (PDE) activity ratio, because a one-step enzymatic reaction of monoester P degradation might be more adaptive for microbial P acquisition than a two-step reaction of diester P degradation. A continuous 10-year P addition experiment was performed in three tropical forests. The activities of PME and PDE, and their ratio in soil, were determined under the hypothesis that the P-fertilized plots where P shortage is relieved would have lower PME:PDE ratios than the unfertilized controls. We demonstrated that long-term P addition in tropical forest soil did not alter the PME:PDE ratio in primary and secondary forests, whereas P fertilization elevated the PME:PDE ratio in planted forest. These results were in contrast to previous results. The long-term, large-scale P fertilization in our study may have reduced litter- and/or throughfall-derived PDE, which negated the lowered PME:PDE ratio via exogenous P inputs.",

keywords = "phosphodiesterase, phosphomonoestarase, phosphorus fertilization, soil extracellular enzymes, tropical forest",

author = "Taiki Mori and Senhao Wang and Cong Wang and Ji Chen and Cheng Peng and Mianhai Zheng and Juan Huang and Faming Wang and Zhanfeng Liu and Jiangming Mo and Wei Zhang",

year = "2023",

month = jun,

doi = "10.1093/jpe/rtac091",

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journal = "Journal of Plant Ecology",

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TY - JOUR

T1 - Effects of long-term phosphorus addition on soil ratios of phosphomonoesterase to phosphodiesterase in three tropical forests

AU - Mori, Taiki

AU - Wang, Senhao

AU - Wang, Cong

AU - Chen, Ji

AU - Peng, Cheng

AU - Zheng, Mianhai

AU - Huang, Juan

AU - Wang, Faming

AU - Liu, Zhanfeng

AU - Mo, Jiangming

AU - Zhang, Wei

PY - 2023/6

Y1 - 2023/6

N2 - Soil microorganisms in tropical forests can adapt to phosphorus (P)-poor conditions by changing the activity ratios of different types of phosphatases. We tested whether microorganisms in P-poor tropical forest soils increased the phosphomonoesterase (PME) to phosphodiesterase (PDE) activity ratio, because a one-step enzymatic reaction of monoester P degradation might be more adaptive for microbial P acquisition than a two-step reaction of diester P degradation. A continuous 10-year P addition experiment was performed in three tropical forests. The activities of PME and PDE, and their ratio in soil, were determined under the hypothesis that the P-fertilized plots where P shortage is relieved would have lower PME:PDE ratios than the unfertilized controls. We demonstrated that long-term P addition in tropical forest soil did not alter the PME:PDE ratio in primary and secondary forests, whereas P fertilization elevated the PME:PDE ratio in planted forest. These results were in contrast to previous results. The long-term, large-scale P fertilization in our study may have reduced litter- and/or throughfall-derived PDE, which negated the lowered PME:PDE ratio via exogenous P inputs.

AB - Soil microorganisms in tropical forests can adapt to phosphorus (P)-poor conditions by changing the activity ratios of different types of phosphatases. We tested whether microorganisms in P-poor tropical forest soils increased the phosphomonoesterase (PME) to phosphodiesterase (PDE) activity ratio, because a one-step enzymatic reaction of monoester P degradation might be more adaptive for microbial P acquisition than a two-step reaction of diester P degradation. A continuous 10-year P addition experiment was performed in three tropical forests. The activities of PME and PDE, and their ratio in soil, were determined under the hypothesis that the P-fertilized plots where P shortage is relieved would have lower PME:PDE ratios than the unfertilized controls. We demonstrated that long-term P addition in tropical forest soil did not alter the PME:PDE ratio in primary and secondary forests, whereas P fertilization elevated the PME:PDE ratio in planted forest. These results were in contrast to previous results. The long-term, large-scale P fertilization in our study may have reduced litter- and/or throughfall-derived PDE, which negated the lowered PME:PDE ratio via exogenous P inputs.

KW - phosphodiesterase

KW - phosphomonoestarase

KW - phosphorus fertilization

KW - soil extracellular enzymes

KW - tropical forest

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DO - 10.1093/jpe/rtac091

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SN - 1752-9921

VL - 16

JO - Journal of Plant Ecology

JF - Journal of Plant Ecology

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ER -

Effects of long-term phosphorus addition on soil ratios of phosphomonoesterase to phosphodiesterase in three tropical forests

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