Stronger dispersal potential of alkaline phosphatase-encoding bacteria ensures higher organic phosphorus mineralization rate

Wenjie Wan; Geoffrey Michael Gadd; Xiang Xiong; Weihong Zhang; Wenzhi Liu; Donglan He; Yarui Cheng; Yuyi Yang

doi:10.1111/1365-2435.14747

Stronger dispersal potential of alkaline phosphatase-encoding bacteria ensures higher organic phosphorus mineralization rate

Wenjie Wan, Geoffrey Michael Gadd, Xiang Xiong, Weihong Zhang, Wenzhi Liu, Donglan He, Yarui Cheng, Yuyi Yang (Lead / Corresponding author)

Molecular Microbiology

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4 Citations (Scopus)

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Abstract

Scientific theory largely neglects linkage between organic phosphorus (Po) mineralization rate and dispersal potential of alkaline phosphatase-encoding bacteria (PEB) containing the phoD gene. Different densities of substrates (i.e. compacted soils, culture media, and soil aggregates) were prepared and molecular tools were used to unveil relationship between dispersal potential of PEB and Po mineralization rate. According to morphological observations and ecological studies, we found that the stronger dispersal potential of PEB ensured a higher Po mineralization rate. Higher Po mineralization rates were found in soil microaggregates than in macroaggregates and silt + clay, and soil Po mineralization rate was related closely to P fractions distributed heterogeneously in aggregates. The phoD gene abundance was notably correlated with Po mineralization rate, and rare PEB mediated Po mineralization. The Bradyrhizobium as identified genus dominated in dramatically heterogeneous PEB community, and stochasticity (70.5%–89.5%) affected more on community assemblages of PEB. The PEB showed a stronger dispersal potential in microaggregates than the other aggregates, as indicated by weaker community stability, stronger species replacement, higher migration rate, lower environmental constraint and broader niche breadth. Overall, our results emphasize that a stronger dispersal potential of PEB ensure a higher Po mineralization rate, and these findings broaden our understanding of how PEB maintain landscape and function in soils. Read the free Plain Language Summary for this article on the Journal blog.

Original language	English
Pages (from-to)	756-769
Number of pages	14
Journal	Functional Ecology
Volume	39
Issue number	3
Early online date	15 Jan 2025
DOIs	https://doi.org/10.1111/1365-2435.14747
Publication status	Published - 4 Mar 2025

Keywords

landscape pattern
phoD gene
phosphorus fractions
rare taxa
stochastic processes
taxonomy versus phylogeny

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics

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10.1111/1365-2435.14747Licence: CC BY

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This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.© 2025 The Author(s). Functional Ecology published by John Wiley & Sons Ltd on behalf of British Ecological Society.
Final published version, 3.15 MBLicence: CC BY

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title = "Stronger dispersal potential of alkaline phosphatase-encoding bacteria ensures higher organic phosphorus mineralization rate",

abstract = "Scientific theory largely neglects linkage between organic phosphorus (Po) mineralization rate and dispersal potential of alkaline phosphatase-encoding bacteria (PEB) containing the phoD gene. Different densities of substrates (i.e. compacted soils, culture media, and soil aggregates) were prepared and molecular tools were used to unveil relationship between dispersal potential of PEB and Po mineralization rate. According to morphological observations and ecological studies, we found that the stronger dispersal potential of PEB ensured a higher Po mineralization rate. Higher Po mineralization rates were found in soil microaggregates than in macroaggregates and silt + clay, and soil Po mineralization rate was related closely to P fractions distributed heterogeneously in aggregates. The phoD gene abundance was notably correlated with Po mineralization rate, and rare PEB mediated Po mineralization. The Bradyrhizobium as identified genus dominated in dramatically heterogeneous PEB community, and stochasticity (70.5\%–89.5\%) affected more on community assemblages of PEB. The PEB showed a stronger dispersal potential in microaggregates than the other aggregates, as indicated by weaker community stability, stronger species replacement, higher migration rate, lower environmental constraint and broader niche breadth. Overall, our results emphasize that a stronger dispersal potential of PEB ensure a higher Po mineralization rate, and these findings broaden our understanding of how PEB maintain landscape and function in soils. Read the free Plain Language Summary for this article on the Journal blog.",

keywords = "landscape pattern, phoD gene, phosphorus fractions, rare taxa, stochastic processes, taxonomy versus phylogeny",

author = "Wenjie Wan and Gadd, \{Geoffrey Michael\} and Xiang Xiong and Weihong Zhang and Wenzhi Liu and Donglan He and Yarui Cheng and Yuyi Yang",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Functional Ecology published by John Wiley \& Sons Ltd on behalf of British Ecological Society.",

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AU - Wan, Wenjie

AU - Gadd, Geoffrey Michael

AU - Xiong, Xiang

AU - Zhang, Weihong

AU - Liu, Wenzhi

AU - He, Donglan

AU - Cheng, Yarui

AU - Yang, Yuyi

PY - 2025/3/4

Y1 - 2025/3/4

N2 - Scientific theory largely neglects linkage between organic phosphorus (Po) mineralization rate and dispersal potential of alkaline phosphatase-encoding bacteria (PEB) containing the phoD gene. Different densities of substrates (i.e. compacted soils, culture media, and soil aggregates) were prepared and molecular tools were used to unveil relationship between dispersal potential of PEB and Po mineralization rate. According to morphological observations and ecological studies, we found that the stronger dispersal potential of PEB ensured a higher Po mineralization rate. Higher Po mineralization rates were found in soil microaggregates than in macroaggregates and silt + clay, and soil Po mineralization rate was related closely to P fractions distributed heterogeneously in aggregates. The phoD gene abundance was notably correlated with Po mineralization rate, and rare PEB mediated Po mineralization. The Bradyrhizobium as identified genus dominated in dramatically heterogeneous PEB community, and stochasticity (70.5%–89.5%) affected more on community assemblages of PEB. The PEB showed a stronger dispersal potential in microaggregates than the other aggregates, as indicated by weaker community stability, stronger species replacement, higher migration rate, lower environmental constraint and broader niche breadth. Overall, our results emphasize that a stronger dispersal potential of PEB ensure a higher Po mineralization rate, and these findings broaden our understanding of how PEB maintain landscape and function in soils. Read the free Plain Language Summary for this article on the Journal blog.

AB - Scientific theory largely neglects linkage between organic phosphorus (Po) mineralization rate and dispersal potential of alkaline phosphatase-encoding bacteria (PEB) containing the phoD gene. Different densities of substrates (i.e. compacted soils, culture media, and soil aggregates) were prepared and molecular tools were used to unveil relationship between dispersal potential of PEB and Po mineralization rate. According to morphological observations and ecological studies, we found that the stronger dispersal potential of PEB ensured a higher Po mineralization rate. Higher Po mineralization rates were found in soil microaggregates than in macroaggregates and silt + clay, and soil Po mineralization rate was related closely to P fractions distributed heterogeneously in aggregates. The phoD gene abundance was notably correlated with Po mineralization rate, and rare PEB mediated Po mineralization. The Bradyrhizobium as identified genus dominated in dramatically heterogeneous PEB community, and stochasticity (70.5%–89.5%) affected more on community assemblages of PEB. The PEB showed a stronger dispersal potential in microaggregates than the other aggregates, as indicated by weaker community stability, stronger species replacement, higher migration rate, lower environmental constraint and broader niche breadth. Overall, our results emphasize that a stronger dispersal potential of PEB ensure a higher Po mineralization rate, and these findings broaden our understanding of how PEB maintain landscape and function in soils. Read the free Plain Language Summary for this article on the Journal blog.

KW - landscape pattern

KW - phoD gene

KW - phosphorus fractions

KW - rare taxa

KW - stochastic processes

KW - taxonomy versus phylogeny

UR - https://www.scopus.com/pages/publications/85215094272

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DO - 10.1111/1365-2435.14747

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VL - 39

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JO - Functional Ecology

JF - Functional Ecology

IS - 3

ER -

Stronger dispersal potential of alkaline phosphatase-encoding bacteria ensures higher organic phosphorus mineralization rate

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Keywords

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