Decreasing carbon allocation belowground in alpine meadow soils by shrubification

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Xiao Ming Mou
  • Fen Can Li
  • Bin Jia
  • Jie Chen
  • Zhen Huan Guan
  • Yu Qiang Li
  • Georg Guggenberger
  • Yakov Kuzyakov
  • Lin Wang
  • Xiao Gang Li

Organisationseinheiten

Externe Organisationen

  • Lanzhou University
  • Chinese Academy of Sciences (CAS)
  • Georg-August-Universität Göttingen
  • Peoples' Friendship University of Russia (RUDN)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer116810
Seitenumfang9
FachzeitschriftGEODERMA
Jahrgang443
Frühes Online-Datum10 Feb. 2024
PublikationsstatusVeröffentlicht - März 2024

Abstract

Distribution of shrubs expanding in grasslands – shrubification – is ongoing worldwide in grasslands and is common on the Qinghai–Tibetan Plateau (QTP). But the consequences of shrubification for plant carbon (C) input and fate in soil are unclear. We used 13C pulse labelling in a meadow on the QTP to compare photosynthetic capacity and photosynthate distribution in shoots, roots, soil and microbial functional groups between herbaceous plants (herbs) and shrubby Potentilla fruticosa. During 3 h of labeling in 13CO2 atmosphere, the 13C amount assimilated by shrubs (0.81 g C/m−2) was only 38 % of that by herbs. Over 8 days after labeling, 13C amount respired jointly by roots and soil microorganisms under shrubs (0.049 g m−2) was less than half of that under herbs. The mean residence time of 13C for respiration jointly by roots and rhizosphere microorganisms was longer under shrubs (0.61 day) than under herbs (0.44 day). Within 22 days after labelling, 13C amounts in roots, soil, and microorganisms were consistently smaller under shrubs than those under herbs. Consequently, shrub P. fruticosa had not only smaller photosynthetic potential, but also allocated less photosynthate belowground and slowed down C cycling in soil compared with herbs. The distribution of total 13C in microbial functional groups indicated by PLFA analysis was similar between herbs and shrubs. Averaged over vegetation patch types, gram negative bacteria and AMF accounted for 22 % and 4 % of the total microbial PLFAs in the 0–20 cm, respectively, but these two functional groups took up 51 % and 23 % of the total 13C absorbed by microorganisms, respectively. This indicates that gram negative bacteria and AMF are major consumers of rhizodeposits. Concluding, shrubification leads to smaller C allocation belowground and slows down C cycling in the soil.

ASJC Scopus Sachgebiete

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Decreasing carbon allocation belowground in alpine meadow soils by shrubification. / Ming Mou, Xiao; Li, Fen Can; Jia, Bin et al.
in: GEODERMA, Jahrgang 443, 116810, 03.2024.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Ming Mou, X, Li, FC, Jia, B, Chen, J, Guan, ZH, Li, YQ, Guggenberger, G, Kuzyakov, Y, Wang, L & Gang Li, X 2024, 'Decreasing carbon allocation belowground in alpine meadow soils by shrubification', GEODERMA, Jg. 443, 116810. https://doi.org/10.1016/j.geoderma.2024.116810
Ming Mou, X., Li, F. C., Jia, B., Chen, J., Guan, Z. H., Li, Y. Q., Guggenberger, G., Kuzyakov, Y., Wang, L., & Gang Li, X. (2024). Decreasing carbon allocation belowground in alpine meadow soils by shrubification. GEODERMA, 443, Artikel 116810. https://doi.org/10.1016/j.geoderma.2024.116810
Ming Mou X, Li FC, Jia B, Chen J, Guan ZH, Li YQ et al. Decreasing carbon allocation belowground in alpine meadow soils by shrubification. GEODERMA. 2024 Mär;443:116810. Epub 2024 Feb 10. doi: 10.1016/j.geoderma.2024.116810
Ming Mou, Xiao ; Li, Fen Can ; Jia, Bin et al. / Decreasing carbon allocation belowground in alpine meadow soils by shrubification. in: GEODERMA. 2024 ; Jahrgang 443.
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title = "Decreasing carbon allocation belowground in alpine meadow soils by shrubification",
abstract = "Distribution of shrubs expanding in grasslands – shrubification – is ongoing worldwide in grasslands and is common on the Qinghai–Tibetan Plateau (QTP). But the consequences of shrubification for plant carbon (C) input and fate in soil are unclear. We used 13C pulse labelling in a meadow on the QTP to compare photosynthetic capacity and photosynthate distribution in shoots, roots, soil and microbial functional groups between herbaceous plants (herbs) and shrubby Potentilla fruticosa. During 3 h of labeling in 13CO2 atmosphere, the 13C amount assimilated by shrubs (0.81 g C/m−2) was only 38 % of that by herbs. Over 8 days after labeling, 13C amount respired jointly by roots and soil microorganisms under shrubs (0.049 g m−2) was less than half of that under herbs. The mean residence time of 13C for respiration jointly by roots and rhizosphere microorganisms was longer under shrubs (0.61 day) than under herbs (0.44 day). Within 22 days after labelling, 13C amounts in roots, soil, and microorganisms were consistently smaller under shrubs than those under herbs. Consequently, shrub P. fruticosa had not only smaller photosynthetic potential, but also allocated less photosynthate belowground and slowed down C cycling in soil compared with herbs. The distribution of total 13C in microbial functional groups indicated by PLFA analysis was similar between herbs and shrubs. Averaged over vegetation patch types, gram negative bacteria and AMF accounted for 22 % and 4 % of the total microbial PLFAs in the 0–20 cm, respectively, but these two functional groups took up 51 % and 23 % of the total 13C absorbed by microorganisms, respectively. This indicates that gram negative bacteria and AMF are major consumers of rhizodeposits. Concluding, shrubification leads to smaller C allocation belowground and slows down C cycling in the soil.",
keywords = "C pulse labelling, Herbaceous plants, phospholipid fatty acids (PLFAs), Photosynthate allocation belowground, Shrub expansion",
author = "{Ming Mou}, Xiao and Li, {Fen Can} and Bin Jia and Jie Chen and Guan, {Zhen Huan} and Li, {Yu Qiang} and Georg Guggenberger and Yakov Kuzyakov and Lin Wang and {Gang Li}, Xiao",
note = "Funding Information: This work was financed by the China Natural Science Foundation Program (Grant No. 42007078) and Youth Science and Technology Fund Program of Gansu Province (Grant No. 22JR5RA083). YK thanks the RUDN University Strategic Academic Leadership Program. ",
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month = mar,
doi = "10.1016/j.geoderma.2024.116810",
language = "English",
volume = "443",
journal = "GEODERMA",
issn = "0016-7061",
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Download

TY - JOUR

T1 - Decreasing carbon allocation belowground in alpine meadow soils by shrubification

AU - Ming Mou, Xiao

AU - Li, Fen Can

AU - Jia, Bin

AU - Chen, Jie

AU - Guan, Zhen Huan

AU - Li, Yu Qiang

AU - Guggenberger, Georg

AU - Kuzyakov, Yakov

AU - Wang, Lin

AU - Gang Li, Xiao

N1 - Funding Information: This work was financed by the China Natural Science Foundation Program (Grant No. 42007078) and Youth Science and Technology Fund Program of Gansu Province (Grant No. 22JR5RA083). YK thanks the RUDN University Strategic Academic Leadership Program.

PY - 2024/3

Y1 - 2024/3

N2 - Distribution of shrubs expanding in grasslands – shrubification – is ongoing worldwide in grasslands and is common on the Qinghai–Tibetan Plateau (QTP). But the consequences of shrubification for plant carbon (C) input and fate in soil are unclear. We used 13C pulse labelling in a meadow on the QTP to compare photosynthetic capacity and photosynthate distribution in shoots, roots, soil and microbial functional groups between herbaceous plants (herbs) and shrubby Potentilla fruticosa. During 3 h of labeling in 13CO2 atmosphere, the 13C amount assimilated by shrubs (0.81 g C/m−2) was only 38 % of that by herbs. Over 8 days after labeling, 13C amount respired jointly by roots and soil microorganisms under shrubs (0.049 g m−2) was less than half of that under herbs. The mean residence time of 13C for respiration jointly by roots and rhizosphere microorganisms was longer under shrubs (0.61 day) than under herbs (0.44 day). Within 22 days after labelling, 13C amounts in roots, soil, and microorganisms were consistently smaller under shrubs than those under herbs. Consequently, shrub P. fruticosa had not only smaller photosynthetic potential, but also allocated less photosynthate belowground and slowed down C cycling in soil compared with herbs. The distribution of total 13C in microbial functional groups indicated by PLFA analysis was similar between herbs and shrubs. Averaged over vegetation patch types, gram negative bacteria and AMF accounted for 22 % and 4 % of the total microbial PLFAs in the 0–20 cm, respectively, but these two functional groups took up 51 % and 23 % of the total 13C absorbed by microorganisms, respectively. This indicates that gram negative bacteria and AMF are major consumers of rhizodeposits. Concluding, shrubification leads to smaller C allocation belowground and slows down C cycling in the soil.

AB - Distribution of shrubs expanding in grasslands – shrubification – is ongoing worldwide in grasslands and is common on the Qinghai–Tibetan Plateau (QTP). But the consequences of shrubification for plant carbon (C) input and fate in soil are unclear. We used 13C pulse labelling in a meadow on the QTP to compare photosynthetic capacity and photosynthate distribution in shoots, roots, soil and microbial functional groups between herbaceous plants (herbs) and shrubby Potentilla fruticosa. During 3 h of labeling in 13CO2 atmosphere, the 13C amount assimilated by shrubs (0.81 g C/m−2) was only 38 % of that by herbs. Over 8 days after labeling, 13C amount respired jointly by roots and soil microorganisms under shrubs (0.049 g m−2) was less than half of that under herbs. The mean residence time of 13C for respiration jointly by roots and rhizosphere microorganisms was longer under shrubs (0.61 day) than under herbs (0.44 day). Within 22 days after labelling, 13C amounts in roots, soil, and microorganisms were consistently smaller under shrubs than those under herbs. Consequently, shrub P. fruticosa had not only smaller photosynthetic potential, but also allocated less photosynthate belowground and slowed down C cycling in soil compared with herbs. The distribution of total 13C in microbial functional groups indicated by PLFA analysis was similar between herbs and shrubs. Averaged over vegetation patch types, gram negative bacteria and AMF accounted for 22 % and 4 % of the total microbial PLFAs in the 0–20 cm, respectively, but these two functional groups took up 51 % and 23 % of the total 13C absorbed by microorganisms, respectively. This indicates that gram negative bacteria and AMF are major consumers of rhizodeposits. Concluding, shrubification leads to smaller C allocation belowground and slows down C cycling in the soil.

KW - C pulse labelling

KW - Herbaceous plants

KW - phospholipid fatty acids (PLFAs)

KW - Photosynthate allocation belowground

KW - Shrub expansion

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DO - 10.1016/j.geoderma.2024.116810

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AN - SCOPUS:85184838554

VL - 443

JO - GEODERMA

JF - GEODERMA

SN - 0016-7061

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