Shift of microbial taxa and metabolisms relying on carbon sources of rhizodeposits and straw of Zea mays L

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  • Zhejiang University
  • Northwest Agriculture and Forestry University
  • University of Western Australia
  • University of California at Davis
  • Ningbo University
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OriginalspracheEnglisch
Aufsatznummer109578
FachzeitschriftSoil Biology and Biochemistry
Jahrgang198
Frühes Online-Datum2 Sept. 2024
PublikationsstatusVeröffentlicht - Nov. 2024

Abstract

Decoding the fundamental taxa that decompose crop rhizodeposits (rhizo-C) and/or straw residue (straw-C) is crucial for understanding the role of plant-derived carbon (C) in driving microbial community assembly and consequent C decomposition. Here, a parallel 13C-labeling design, DNA-SIP, and metagenomics techniques were combined to separate maize rhizo-C utilizers from straw-C utilizers in agriculture soils containing both C sources. Also, by comparing bacterial utilizers and their C metabolisms in soils amended with a single C source (e.g., straw-13C only) and two C sources (e.g., straw-13C and rhizo-12C), we investigated the shift of composition and metabolisms of soil bacterial utilizers responding to C sources shift (e.g., compositional and metabolic changes of straw-13C utilizers from soil containing straw-13C to soil containing both straw-13C and rhizo-12C). We revealed i) Proteobacteria predominantly utilized rhizo-13C, while Firmicutes dominated the community specializing in straw-13C decomposition in soil containing both straw-C and rhizo-C; ii) the planted maize (i.e. rhizo-C input) changed community composition and metabolisms of straw-C utilizers, which shifted from K-strategists characterized by an enrichment of lignin-degrading genes to r-strategists which exhibited an enrichment of genes related to polysaccharide degradation. This metabolic shift of straw-C utilizer ultimately reduced straw-13C mineralization by 25.6% when maize was planted. This study identified the distinct utilizers of rhizo-C and straw-C in soils containing both C sources, and shed light on the shift of bacterial community and their metabolic activities responding to the changes of maize-derived C sources.

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Shift of microbial taxa and metabolisms relying on carbon sources of rhizodeposits and straw of Zea mays L. / Fu, Yingyi; Luo, Yu; Qi, Jiejun et al.
in: Soil Biology and Biochemistry, Jahrgang 198, 109578, 11.2024.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Fu Y, Luo Y, Qi J, He X, Zhang H, Guggenberger G et al. Shift of microbial taxa and metabolisms relying on carbon sources of rhizodeposits and straw of Zea mays L. Soil Biology and Biochemistry. 2024 Nov;198:109578. Epub 2024 Sep 2. doi: 10.1016/j.soilbio.2024.109578
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abstract = "Decoding the fundamental taxa that decompose crop rhizodeposits (rhizo-C) and/or straw residue (straw-C) is crucial for understanding the role of plant-derived carbon (C) in driving microbial community assembly and consequent C decomposition. Here, a parallel 13C-labeling design, DNA-SIP, and metagenomics techniques were combined to separate maize rhizo-C utilizers from straw-C utilizers in agriculture soils containing both C sources. Also, by comparing bacterial utilizers and their C metabolisms in soils amended with a single C source (e.g., straw-13C only) and two C sources (e.g., straw-13C and rhizo-12C), we investigated the shift of composition and metabolisms of soil bacterial utilizers responding to C sources shift (e.g., compositional and metabolic changes of straw-13C utilizers from soil containing straw-13C to soil containing both straw-13C and rhizo-12C). We revealed i) Proteobacteria predominantly utilized rhizo-13C, while Firmicutes dominated the community specializing in straw-13C decomposition in soil containing both straw-C and rhizo-C; ii) the planted maize (i.e. rhizo-C input) changed community composition and metabolisms of straw-C utilizers, which shifted from K-strategists characterized by an enrichment of lignin-degrading genes to r-strategists which exhibited an enrichment of genes related to polysaccharide degradation. This metabolic shift of straw-C utilizer ultimately reduced straw-13C mineralization by 25.6% when maize was planted. This study identified the distinct utilizers of rhizo-C and straw-C in soils containing both C sources, and shed light on the shift of bacterial community and their metabolic activities responding to the changes of maize-derived C sources.",
keywords = "Agro-ecosystem, Bacterial community, Carbon metabolism, Continuous CO labeling, Rhizo-C/straw utilizers, SIP-Metagenome",
author = "Yingyi Fu and Yu Luo and Jiejun Qi and Xinhua He and Haoqing Zhang and Georg Guggenberger and Jianming Xu",
note = "Publisher Copyright: {\textcopyright} 2024",
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TY - JOUR

T1 - Shift of microbial taxa and metabolisms relying on carbon sources of rhizodeposits and straw of Zea mays L

AU - Fu, Yingyi

AU - Luo, Yu

AU - Qi, Jiejun

AU - He, Xinhua

AU - Zhang, Haoqing

AU - Guggenberger, Georg

AU - Xu, Jianming

N1 - Publisher Copyright: © 2024

PY - 2024/11

Y1 - 2024/11

N2 - Decoding the fundamental taxa that decompose crop rhizodeposits (rhizo-C) and/or straw residue (straw-C) is crucial for understanding the role of plant-derived carbon (C) in driving microbial community assembly and consequent C decomposition. Here, a parallel 13C-labeling design, DNA-SIP, and metagenomics techniques were combined to separate maize rhizo-C utilizers from straw-C utilizers in agriculture soils containing both C sources. Also, by comparing bacterial utilizers and their C metabolisms in soils amended with a single C source (e.g., straw-13C only) and two C sources (e.g., straw-13C and rhizo-12C), we investigated the shift of composition and metabolisms of soil bacterial utilizers responding to C sources shift (e.g., compositional and metabolic changes of straw-13C utilizers from soil containing straw-13C to soil containing both straw-13C and rhizo-12C). We revealed i) Proteobacteria predominantly utilized rhizo-13C, while Firmicutes dominated the community specializing in straw-13C decomposition in soil containing both straw-C and rhizo-C; ii) the planted maize (i.e. rhizo-C input) changed community composition and metabolisms of straw-C utilizers, which shifted from K-strategists characterized by an enrichment of lignin-degrading genes to r-strategists which exhibited an enrichment of genes related to polysaccharide degradation. This metabolic shift of straw-C utilizer ultimately reduced straw-13C mineralization by 25.6% when maize was planted. This study identified the distinct utilizers of rhizo-C and straw-C in soils containing both C sources, and shed light on the shift of bacterial community and their metabolic activities responding to the changes of maize-derived C sources.

AB - Decoding the fundamental taxa that decompose crop rhizodeposits (rhizo-C) and/or straw residue (straw-C) is crucial for understanding the role of plant-derived carbon (C) in driving microbial community assembly and consequent C decomposition. Here, a parallel 13C-labeling design, DNA-SIP, and metagenomics techniques were combined to separate maize rhizo-C utilizers from straw-C utilizers in agriculture soils containing both C sources. Also, by comparing bacterial utilizers and their C metabolisms in soils amended with a single C source (e.g., straw-13C only) and two C sources (e.g., straw-13C and rhizo-12C), we investigated the shift of composition and metabolisms of soil bacterial utilizers responding to C sources shift (e.g., compositional and metabolic changes of straw-13C utilizers from soil containing straw-13C to soil containing both straw-13C and rhizo-12C). We revealed i) Proteobacteria predominantly utilized rhizo-13C, while Firmicutes dominated the community specializing in straw-13C decomposition in soil containing both straw-C and rhizo-C; ii) the planted maize (i.e. rhizo-C input) changed community composition and metabolisms of straw-C utilizers, which shifted from K-strategists characterized by an enrichment of lignin-degrading genes to r-strategists which exhibited an enrichment of genes related to polysaccharide degradation. This metabolic shift of straw-C utilizer ultimately reduced straw-13C mineralization by 25.6% when maize was planted. This study identified the distinct utilizers of rhizo-C and straw-C in soils containing both C sources, and shed light on the shift of bacterial community and their metabolic activities responding to the changes of maize-derived C sources.

KW - Agro-ecosystem

KW - Bacterial community

KW - Carbon metabolism

KW - Continuous CO labeling

KW - Rhizo-C/straw utilizers

KW - SIP-Metagenome

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U2 - 10.1016/j.soilbio.2024.109578

DO - 10.1016/j.soilbio.2024.109578

M3 - Article

AN - SCOPUS:85202941450

VL - 198

JO - Soil Biology and Biochemistry

JF - Soil Biology and Biochemistry

SN - 0038-0717

M1 - 109578

ER -

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