Assessing turnover of microbial biomass phosphorus: Combination of an isotopic dilution method with a mass balance model

Microbial biomass phosphorus (P) can play an important role in P cycling and availability to plants by acting as a source (remineralization) or sink (immobilization) of phosphate ions (iP). To assess the role of the microbial P pools, both the dynamics (i.e. the turnover) and the size of the microbi...

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Published in:Soil biology & biochemistry Vol. 42; no. 12; pp. 2231 - 2240
Main Authors: Achat, David L., Morel, Christian, Bakker, Mark R., Augusto, Laurent, Pellerin, Sylvain, Gallet-Budynek, Anne, Gonzalez, Maya
Format: Journal Article
Language:English
Published: Amsterdam Elsevier Ltd 01.12.2010
Elsevier
Subjects:
Agricultural sciences
Agronomy. Soil science and plant productions
Biochemistry and biology
biogeochemical cycles
Biological and medical sciences
Chemical, physicochemical, biochemical and biological properties
Forest ecosystem
forest soils
forest trees
France
Fundamental and applied biological sciences. Psychology
immobilization in soil
Isotopic dilution method
Life Sciences
Mass balance model
Microbial biomass
Microbiology
mineralization
nutrient availability
nutrient uptake
P availability
P cycling
phosphates
Phosphorus
Physics, chemistry, biochemistry and biology of agricultural and forest soils
plant nutrition
simulation models
soil microorganisms
soil organic matter
Soil science
Soil study
temperate forests
temporal variation
Turnover
France
P cycling
Isotopic dilution method
P availability
Forest ecosystem
Turnover
Phosphorus
Microbial biomass
Mass balance model
Forests
Forest zone
Available nutrient
Isotope dilution
Modeling
Ecosystem
Soil science
Material balance
PHOSPHORUS
MICROBIAL BIOMASS
MASS BALANCE MODEL
TURNOVER
P AVAILABILITY
FOREST ECOSYSTEM
ISOTOPIC DILUTION METHOD
P CYCLING
ISSN:0038-0717, 1879-3428
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Abstract Microbial biomass phosphorus (P) can play an important role in P cycling and availability to plants by acting as a source (remineralization) or sink (immobilization) of phosphate ions (iP). To assess the role of the microbial P pools, both the dynamics (i.e. the turnover) and the size of the microbial P pools were studied in forest soils. Combining an isotopic dilution method with a modelling approach, we showed the existence of two pools of microbial P with different dynamics and therefore of different importance in soil P availability and cycling. In particular, we showed that the largest pool of microbial P (80%) had a fast turnover (nine days). Microbial P increased with an increase in soil organic matter and represented up to 53% of total P in contrasting forest soils. By combining these results with the turnover times of microbial P obtained in the modelling study, we evaluated that 8.5–17.3 kg P ha −1 of microbial P could turn over in a few days. This suggests that microbial biomass P is a potentially significant source of available iP, and that micro-organisms can play a major role in P cycling in the forest studied here. However, microbial biomass can also be in competition with the trees since most of the remineralized P could be immobilized again in the microbial turnover.
AbstractList Microbial biomass phosphorus (P) can play an important role in P cycling and availability to plants by acting as a source (remineralization) or sink (immobilization) of phosphate ions (iP). To assess the role of the microbial P pools, both the dynamics (i.e. the turnover) and the size of the microbial P pools were studied in forest soils. Combining an isotopic dilution method with a modelling approach, we showed the existence of two pools of microbial P with different dynamics and therefore of different importance in soil P availability and cycling. In particular, we showed that the largest pool of microbial P (80%) had a fast turnover (nine days). Microbial P increased with an increase in soil organic matter and represented up to 53% of total P in contrasting forest soils. By combining these results with the turnover times of microbial P obtained in the modelling study, we evaluated that 8.5–17.3 kg P ha−1 of microbial P could turn over in a few days. This suggests that microbial biomass P is a potentially significant source of available iP, and that micro-organisms can play a major role in P cycling in the forest studied here. However, microbial biomass can also be in competition with the trees since most of the remineralized P could be immobilized again in the microbial turnover.
Microbial biomass phosphorus (P) can play an important role in P cycling and availability to plants by acting as a source (remineralization) or sink (immobilization) of phosphate ions (iP). To assess the role of the microbial P pools, both the dynamics (i.e. the turnover) and the size of the microbial P pools were studied in forest soils. Combining an isotopic dilution method with a modelling approach, we showed the existence of two pools of microbial P with different dynamics and therefore of different importance in soil P availability and cycling. In particular, we showed that the largest pool of microbial P (80%) had a fast turnover (nine days). Microbial P increased with an increase in soil organic matter and represented up to 53% of total P in contrasting forest soils. By combining these results with the turnover times of microbial P obtained in the modelling study, we evaluated that 8.5-17.3 kg P ha super(-1) of microbial P could turn over in a few days. This suggests that microbial biomass P is a potentially significant source of available iP, and that micro-organisms can play a major role in P cycling in the forest studied here. However, microbial biomass can also be in competition with the trees since most of the remineralized P could be immobilized again in the microbial turnover.
Microbial biomass phosphorus (P) can play an important role in P cycling and availability to plants by acting as a source (remineralization) or sink (immobilization) of phosphate ions (iP). To assess the role of the microbial P pools, both the dynamics (i.e. the turnover) and the size of the microbial P pools were studied in forest soils. Combining an isotopic dilution method with a modelling approach, we showed the existence of two pools of microbial P with different dynamics and therefore of different importance in soil P availability and cycling. In particular, we showed that the largest pool of microbial P (80%) had a fast turnover (nine days). Microbial P increased with an increase in soil organic matter and represented up to 53% of total P in contrasting forest soils. By combining these results with the turnover times of microbial P obtained in the modelling study, we evaluated that 8.5–17.3 kg P ha −1 of microbial P could turn over in a few days. This suggests that microbial biomass P is a potentially significant source of available iP, and that micro-organisms can play a major role in P cycling in the forest studied here. However, microbial biomass can also be in competition with the trees since most of the remineralized P could be immobilized again in the microbial turnover.
Author Gallet-Budynek, Anne
Pellerin, Sylvain
Morel, Christian
Gonzalez, Maya
Achat, David L.
Augusto, Laurent
Bakker, Mark R.
Author_xml – sequence: 1
  givenname: David L.
  surname: Achat
  fullname: Achat, David L.
  email: dachat@bordeaux.inra.fr
  organization: ENITA de Bordeaux, UMR 1220 TCEM (INRA-ENITAB), 1 cours du Général de Gaulle, F-33175, France
– sequence: 2
  givenname: Christian
  surname: Morel
  fullname: Morel, Christian
  organization: INRA, UMR 1220 TCEM (INRA-ENITAB), 71 avenue E Bourlaux, F-33883 Villenave d’Ornon, France
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  givenname: Mark R.
  surname: Bakker
  fullname: Bakker, Mark R.
  organization: ENITA de Bordeaux, UMR 1220 TCEM (INRA-ENITAB), 1 cours du Général de Gaulle, F-33175, France
– sequence: 4
  givenname: Laurent
  surname: Augusto
  fullname: Augusto, Laurent
  organization: INRA, UMR 1220 TCEM (INRA-ENITAB), 71 avenue E Bourlaux, F-33883 Villenave d’Ornon, France
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  givenname: Sylvain
  surname: Pellerin
  fullname: Pellerin, Sylvain
  organization: INRA, UMR 1220 TCEM (INRA-ENITAB), 71 avenue E Bourlaux, F-33883 Villenave d’Ornon, France
– sequence: 6
  givenname: Anne
  surname: Gallet-Budynek
  fullname: Gallet-Budynek, Anne
  organization: INRA, UMR 1220 TCEM (INRA-ENITAB), 71 avenue E Bourlaux, F-33883 Villenave d’Ornon, France
– sequence: 7
  givenname: Maya
  surname: Gonzalez
  fullname: Gonzalez, Maya
  organization: ENITA de Bordeaux, UMR 1220 TCEM (INRA-ENITAB), 1 cours du Général de Gaulle, F-33175, France
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Issue 12
Keywords P cycling
Isotopic dilution method
P availability
Forest ecosystem
Turnover
Phosphorus
Microbial biomass
Mass balance model
Forests
Forest zone
Available nutrient
Isotope dilution
Modeling
Ecosystem
Soil science
Material balance
PHOSPHORUS
MICROBIAL BIOMASS
MASS BALANCE MODEL
TURNOVER
P AVAILABILITY
FOREST ECOSYSTEM
ISOTOPIC DILUTION METHOD
P CYCLING
Language English
License CC BY 4.0
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PublicationDate_xml – month: 12
  year: 2010
  text: 2010-12-01
  day: 01
PublicationDecade 2010
PublicationPlace Amsterdam
PublicationPlace_xml – name: Amsterdam
PublicationTitle Soil biology & biochemistry
PublicationYear 2010
Publisher Elsevier Ltd
Elsevier
Publisher_xml – name: Elsevier Ltd
– name: Elsevier
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Snippet Microbial biomass phosphorus (P) can play an important role in P cycling and availability to plants by acting as a source (remineralization) or sink...
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SubjectTerms Agricultural sciences
Agronomy. Soil science and plant productions
Biochemistry and biology
biogeochemical cycles
Biological and medical sciences
Chemical, physicochemical, biochemical and biological properties
Forest ecosystem
forest soils
forest trees
France
Fundamental and applied biological sciences. Psychology
immobilization in soil
Isotopic dilution method
Life Sciences
Mass balance model
Microbial biomass
Microbiology
mineralization
nutrient availability
nutrient uptake
P availability
P cycling
phosphates
Phosphorus
Physics, chemistry, biochemistry and biology of agricultural and forest soils
plant nutrition
simulation models
soil microorganisms
soil organic matter
Soil science
Soil study
temperate forests
temporal variation
Turnover
Title Assessing turnover of microbial biomass phosphorus: Combination of an isotopic dilution method with a mass balance model
URI https://dx.doi.org/10.1016/j.soilbio.2010.08.023
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Volume 42
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