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Organic and inorganic sulfur and nitrogen uptake by co-existing grassland plant species competing with soil microorganisms. / Ma, Qingxu; Xu, Meng; Liu, Mengjiao et al.
In: Soil Biology and Biochemistry, Vol. 168, 01.05.2022.

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Ma Q, Xu M, Liu M, Cao X, Hill PW, Chadwick DR et al. Organic and inorganic sulfur and nitrogen uptake by co-existing grassland plant species competing with soil microorganisms. Soil Biology and Biochemistry. 2022 May 1;168. Epub 2022 Mar 8. doi: 10.1016/j.soilbio.2022.108627

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Ma, Qingxu ; Xu, Meng ; Liu, Mengjiao et al. / Organic and inorganic sulfur and nitrogen uptake by co-existing grassland plant species competing with soil microorganisms. In: Soil Biology and Biochemistry. 2022 ; Vol. 168.

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TY - JOUR

T1 - Organic and inorganic sulfur and nitrogen uptake by co-existing grassland plant species competing with soil microorganisms

AU - Ma, Qingxu

AU - Xu, Meng

AU - Liu, Mengjiao

AU - Cao, Xiaochuang

AU - Hill, Paul W.

AU - Chadwick, David R.

AU - Wu, Lianghuan

AU - Jones, Davey L.

PY - 2022/5/1

Y1 - 2022/5/1

N2 - Cysteine (Cys) and methionine (Met) are unique amino acids that contain not only nitrogen (N) but also sulfur (S); thus, they are a source of S for plants under low-soil-SO42- conditions. However, whether low-molecular-weight organic N and S can be utilised by plants or contribute to plant growth remains unknown. Therefore, this study aimed to examine the uptake of organic and inorganic N and S by plants and the role of microbial decomposition under monocropping and intercropping based on 13C, 15N, 14C, and 35S quad labelling. As indicated by the 13C/14C uptake, clover, millet, and ryegrass utilised 0.24–1.68% of the added Cys and Met within 6 h and encountered considerable competition from soil microorganisms. The added Met and Cys were rapidly utilised by microorganisms, and part of the N was subsequently released as inorganic N, which was taken up by plants (15N-Cys: 9.3–15.2%; 15N-Met: 5.9–13.4%) within 6 h. Six hours after addition, 57.8–78.5% of the 35S-Met and 26.2–56.0% of the 35S-Cys were retained in the microbial biomass, while more 35S-Cys was mineralised to SO42−. Plants took up 5.5–12.4% of 35S-Cys and only 3.4–6.0% of 35S-Met, and 35S uptake was dominated by inorganic S after the mineralisation of Cys and Met. N uptake from Cys and Met accounted for less than 1% of the total N uptake from the soil, while S uptake from Cys and Met accounted for 9.3–27.0% and 2.8–11.8% of the total S uptake from the soil, respectively. Additionally, Cys was more rapidly mineralised to SO42− by soil microbes than Met; the produced SO42− was further utilised by plant roots. The contributions of Cys and Met to the total N and S uptake were the highest in millet monocropping while intercropping altered the relative contributions of organic and inorganic N and S. Overall, soil soluble Cys and Met played a limited role in plant N uptake but were an important source of plant S uptake.

AB - Cysteine (Cys) and methionine (Met) are unique amino acids that contain not only nitrogen (N) but also sulfur (S); thus, they are a source of S for plants under low-soil-SO42- conditions. However, whether low-molecular-weight organic N and S can be utilised by plants or contribute to plant growth remains unknown. Therefore, this study aimed to examine the uptake of organic and inorganic N and S by plants and the role of microbial decomposition under monocropping and intercropping based on 13C, 15N, 14C, and 35S quad labelling. As indicated by the 13C/14C uptake, clover, millet, and ryegrass utilised 0.24–1.68% of the added Cys and Met within 6 h and encountered considerable competition from soil microorganisms. The added Met and Cys were rapidly utilised by microorganisms, and part of the N was subsequently released as inorganic N, which was taken up by plants (15N-Cys: 9.3–15.2%; 15N-Met: 5.9–13.4%) within 6 h. Six hours after addition, 57.8–78.5% of the 35S-Met and 26.2–56.0% of the 35S-Cys were retained in the microbial biomass, while more 35S-Cys was mineralised to SO42−. Plants took up 5.5–12.4% of 35S-Cys and only 3.4–6.0% of 35S-Met, and 35S uptake was dominated by inorganic S after the mineralisation of Cys and Met. N uptake from Cys and Met accounted for less than 1% of the total N uptake from the soil, while S uptake from Cys and Met accounted for 9.3–27.0% and 2.8–11.8% of the total S uptake from the soil, respectively. Additionally, Cys was more rapidly mineralised to SO42− by soil microbes than Met; the produced SO42− was further utilised by plant roots. The contributions of Cys and Met to the total N and S uptake were the highest in millet monocropping while intercropping altered the relative contributions of organic and inorganic N and S. Overall, soil soluble Cys and Met played a limited role in plant N uptake but were an important source of plant S uptake.

KW - Organic sulfur mineralisation

KW - Soil organic nitrogen

KW - Soil sulfur cycling

KW - Intercropping

KW - Nutrient cycling

U2 - 10.1016/j.soilbio.2022.108627

DO - 10.1016/j.soilbio.2022.108627

M3 - Article

VL - 168

JO - Soil Biology and Biochemistry

JF - Soil Biology and Biochemistry

SN - 0038-0717

ER -