Microbial response on changing C:P stoichiometry in steppe soils of Northern Kazakhstan

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  • Ningbo University
  • The Second Surveying and Mapping Institute of Hunan Province
  • Zhejiang A&F University (ZAFU)
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OriginalspracheEnglisch
Seiten (von - bis)375-389
Seitenumfang15
FachzeitschriftPlant and soil
Jahrgang493
Ausgabenummer1-2
Frühes Online-Datum23 Aug. 2023
PublikationsstatusVeröffentlicht - Dez. 2023

Abstract

Background and aims: The stoichiometric ratio of carbon (C): phosphorus (P) acquisition is strongly correlated with soil available C:P ratio. However how the stoichiometric relationship between acquiring C and P through microbial metabolism affects bioavailable P is poorly understood in semi-arid agricultural ecosystems. Methods: Our objective was to investigate the underlying mechanisms of the P availability in typical P-limited steppe soil from Kazakhstan in response to mineral nutrient (Na2HPO4) with and without Dactylis glomerata L. leaves addition in a 38-day incubation experiment. Results: Four bioavailable P fractions content (CaCl2-P, Citrate-P, Enzyme-P, and HCl-P) were improved. Sole application of P fertilizer decreased the maximal velocity (Vmax) of P acquisition enzyme (phosphomonoesterase) but increased microbial C limitation, resulting in increasing the ratio of C to P acquisition but decreasing the ratio of available dissolved organic C: Olsen-P. In contrast, plant residues returning (the application of sole D. glomerata leaves and the combined application of D.glomerata and mineral P) increased Vmax of C (β-1, 4-glucosidase, β-D-cellobiosidase, β-1, 4-xylosidase) and P acquisition enzymes, however decreasing microbial C and P limitation through improving microbial metabolism. Furthermore, the spearman correlation and piecewiseSEM analysis suggested that microbial C limitation and EEAC:P had a negative effect on P availability, illustrating that the decreasing of microbial C limitation can improve soil bioavailable P. Conclusion: The decomposition of organic residues eliminated microbial P limitation and increased P availability by allocating C and P acquisition enzymes to balance the stoichiometric ratio of microbial C and P demand. Graphical Abstract: [Figure not available: see fulltext.].

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Microbial response on changing C:P stoichiometry in steppe soils of Northern Kazakhstan. / Liu, Yuhuai; Shibistova, Olga; Cai, Guan et al.
in: Plant and soil, Jahrgang 493, Nr. 1-2, 12.2023, S. 375-389.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Liu Y, Shibistova O, Cai G, Sauheitl L, Xiao M, Ge T et al. Microbial response on changing C:P stoichiometry in steppe soils of Northern Kazakhstan. Plant and soil. 2023 Dez;493(1-2):375-389. Epub 2023 Aug 23. doi: 10.1007/s11104-023-06235-9
Liu, Yuhuai ; Shibistova, Olga ; Cai, Guan et al. / Microbial response on changing C:P stoichiometry in steppe soils of Northern Kazakhstan. in: Plant and soil. 2023 ; Jahrgang 493, Nr. 1-2. S. 375-389.
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title = "Microbial response on changing C:P stoichiometry in steppe soils of Northern Kazakhstan",
abstract = "Background and aims: The stoichiometric ratio of carbon (C): phosphorus (P) acquisition is strongly correlated with soil available C:P ratio. However how the stoichiometric relationship between acquiring C and P through microbial metabolism affects bioavailable P is poorly understood in semi-arid agricultural ecosystems. Methods: Our objective was to investigate the underlying mechanisms of the P availability in typical P-limited steppe soil from Kazakhstan in response to mineral nutrient (Na2HPO4) with and without Dactylis glomerata L. leaves addition in a 38-day incubation experiment. Results: Four bioavailable P fractions content (CaCl2-P, Citrate-P, Enzyme-P, and HCl-P) were improved. Sole application of P fertilizer decreased the maximal velocity (Vmax) of P acquisition enzyme (phosphomonoesterase) but increased microbial C limitation, resulting in increasing the ratio of C to P acquisition but decreasing the ratio of available dissolved organic C: Olsen-P. In contrast, plant residues returning (the application of sole D. glomerata leaves and the combined application of D.glomerata and mineral P) increased Vmax of C (β-1, 4-glucosidase, β-D-cellobiosidase, β-1, 4-xylosidase) and P acquisition enzymes, however decreasing microbial C and P limitation through improving microbial metabolism. Furthermore, the spearman correlation and piecewiseSEM analysis suggested that microbial C limitation and EEAC:P had a negative effect on P availability, illustrating that the decreasing of microbial C limitation can improve soil bioavailable P. Conclusion: The decomposition of organic residues eliminated microbial P limitation and increased P availability by allocating C and P acquisition enzymes to balance the stoichiometric ratio of microbial C and P demand. Graphical Abstract: [Figure not available: see fulltext.].",
keywords = "Bioavailable P, C:P stoichiometric ratio, Kazakhstan, Microbial C and P limitation, Steppe soil",
author = "Yuhuai Liu and Olga Shibistova and Guan Cai and Leopold Sauheitl and Mouliang Xiao and Tida Ge and Georg Guggenberger",
note = "Funding Information: We gratefully acknowledge the German Ministry of Education and Science (BMBF) for funding the study in the framework of the CLIENT II program within the project ReKKS (funding number 01LZ1704A). Yuhuai Liu is grateful for financial support by the Chinese National Study Abroad Fund. We thank Institute of Soil Science, Leibniz University Hannover for technical assistance. ",
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TY - JOUR

T1 - Microbial response on changing C:P stoichiometry in steppe soils of Northern Kazakhstan

AU - Liu, Yuhuai

AU - Shibistova, Olga

AU - Cai, Guan

AU - Sauheitl, Leopold

AU - Xiao, Mouliang

AU - Ge, Tida

AU - Guggenberger, Georg

N1 - Funding Information: We gratefully acknowledge the German Ministry of Education and Science (BMBF) for funding the study in the framework of the CLIENT II program within the project ReKKS (funding number 01LZ1704A). Yuhuai Liu is grateful for financial support by the Chinese National Study Abroad Fund. We thank Institute of Soil Science, Leibniz University Hannover for technical assistance.

PY - 2023/12

Y1 - 2023/12

N2 - Background and aims: The stoichiometric ratio of carbon (C): phosphorus (P) acquisition is strongly correlated with soil available C:P ratio. However how the stoichiometric relationship between acquiring C and P through microbial metabolism affects bioavailable P is poorly understood in semi-arid agricultural ecosystems. Methods: Our objective was to investigate the underlying mechanisms of the P availability in typical P-limited steppe soil from Kazakhstan in response to mineral nutrient (Na2HPO4) with and without Dactylis glomerata L. leaves addition in a 38-day incubation experiment. Results: Four bioavailable P fractions content (CaCl2-P, Citrate-P, Enzyme-P, and HCl-P) were improved. Sole application of P fertilizer decreased the maximal velocity (Vmax) of P acquisition enzyme (phosphomonoesterase) but increased microbial C limitation, resulting in increasing the ratio of C to P acquisition but decreasing the ratio of available dissolved organic C: Olsen-P. In contrast, plant residues returning (the application of sole D. glomerata leaves and the combined application of D.glomerata and mineral P) increased Vmax of C (β-1, 4-glucosidase, β-D-cellobiosidase, β-1, 4-xylosidase) and P acquisition enzymes, however decreasing microbial C and P limitation through improving microbial metabolism. Furthermore, the spearman correlation and piecewiseSEM analysis suggested that microbial C limitation and EEAC:P had a negative effect on P availability, illustrating that the decreasing of microbial C limitation can improve soil bioavailable P. Conclusion: The decomposition of organic residues eliminated microbial P limitation and increased P availability by allocating C and P acquisition enzymes to balance the stoichiometric ratio of microbial C and P demand. Graphical Abstract: [Figure not available: see fulltext.].

AB - Background and aims: The stoichiometric ratio of carbon (C): phosphorus (P) acquisition is strongly correlated with soil available C:P ratio. However how the stoichiometric relationship between acquiring C and P through microbial metabolism affects bioavailable P is poorly understood in semi-arid agricultural ecosystems. Methods: Our objective was to investigate the underlying mechanisms of the P availability in typical P-limited steppe soil from Kazakhstan in response to mineral nutrient (Na2HPO4) with and without Dactylis glomerata L. leaves addition in a 38-day incubation experiment. Results: Four bioavailable P fractions content (CaCl2-P, Citrate-P, Enzyme-P, and HCl-P) were improved. Sole application of P fertilizer decreased the maximal velocity (Vmax) of P acquisition enzyme (phosphomonoesterase) but increased microbial C limitation, resulting in increasing the ratio of C to P acquisition but decreasing the ratio of available dissolved organic C: Olsen-P. In contrast, plant residues returning (the application of sole D. glomerata leaves and the combined application of D.glomerata and mineral P) increased Vmax of C (β-1, 4-glucosidase, β-D-cellobiosidase, β-1, 4-xylosidase) and P acquisition enzymes, however decreasing microbial C and P limitation through improving microbial metabolism. Furthermore, the spearman correlation and piecewiseSEM analysis suggested that microbial C limitation and EEAC:P had a negative effect on P availability, illustrating that the decreasing of microbial C limitation can improve soil bioavailable P. Conclusion: The decomposition of organic residues eliminated microbial P limitation and increased P availability by allocating C and P acquisition enzymes to balance the stoichiometric ratio of microbial C and P demand. Graphical Abstract: [Figure not available: see fulltext.].

KW - Bioavailable P

KW - C:P stoichiometric ratio

KW - Kazakhstan

KW - Microbial C and P limitation

KW - Steppe soil

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U2 - 10.1007/s11104-023-06235-9

DO - 10.1007/s11104-023-06235-9

M3 - Article

AN - SCOPUS:85168586169

VL - 493

SP - 375

EP - 389

JO - Plant and soil

JF - Plant and soil

SN - 0032-079X

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ER -

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