Microbial assemblies with distinct trophic strategies drive changes in soil microbial carbon use efficiency along vegetation primary succession in a glacier retreat area of the southeastern Tibetan Plateau

Soil microbial carbon use efficiency (CUE) is a vital physiological parameter in assessing carbon turnover. Yet, how the microbial assemblies with distinct trophic strategies regulate the soil microbial CUE remains elusive. Based on the oligotrophic-copiotrophic framework, we explored the role of mi...

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Published in:The Science of the total environment 2023-04, Vol.867, p.161587-161587, Article 161587
Main Authors: Ma, Shenglan, Zhu, Wanze, Wang, Wenwu, Li, Xia, Sheng, Zheliang
Format: Article
Language:English
Subjects:
13C-labeled glucose
Bacteria
Carbon
Ice Cover - microbiology
Microbial carbon use efficiency
Soil
Soil Microbiology
Soil microorganisms
Tibet
Tibetan Plateau
Trophic strategies
Vegetation primary succession
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Summary:Soil microbial carbon use efficiency (CUE) is a vital physiological parameter in assessing carbon turnover. Yet, how the microbial assemblies with distinct trophic strategies regulate the soil microbial CUE remains elusive. Based on the oligotrophic-copiotrophic framework, we explored the role of microbial taxa with different trophic strategies in mediating microbial CUE (determined by a 13C-labeled approach) along the vegetation primary succession in Hailuogou glacier retreat area of the southeastern Tibetan Plateau. Results showed that soil microbial CUE ranged from 0.54 to 0.72 (averaging 0.62 ± 0.01 across all samples) and increased staggeringly along the vegetation succession. Microbial assemblies with distinct trophic strategies were crucial regulators of soil microbial CUE. Specifically, microbial CUE increased with microbial oligotroph: copiotroph ratios, oligotroph-dominated stage had a higher microbial CUE than copiotroph-dominated ones. The prevalence of oligotrophic members would be the underlying microbial mechanism for the high microbial CUE. Given that oligotrophs predominate in more recalcitrant carbon soils and their higher microbial CUE, we speculate that oligotrophs are likely to potentially enhance carbon sequestration in soils. In addition, the responses of the microbial CUE to fungal oligotroph: copiotroph ratios were higher than bacterial ones. Fungal taxa may play a dominant role in shaping microbial CUE relative to bacterial members. Overall, our results constructed close associations between microbial trophic strategies and CUE and provide direct evidence regarding how microbial trophic strategies regulate microbial CUE. This study is a significant step forward for elucidating the physiological mechanisms regulating microbial CUE and has significant implications for understanding microbial-mediated carbon cycling processes. [Display omitted] •Microbial communities shift from copiotrophs to oligotrophs along the vegetation succession.•Soil microbial CUE increased with the microbial oligotroph: copiotroph ratios.•Fungal taxa may play a dominant role in shaping CUE relative to bacterial members.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2023.161587