Glucose priming effect on microbial intercellular metabolic flux diversity in a marine intertidal sediment Article Swipe
Tao Ji
,
ZhiAo Xu
,
Lihong Wen
,
Yuxue Yang
,
Yue Wu
,
Xueqin Zhao
,
Ruilian Yao
,
Ru-Long Liu
,
Yunping Xu
,
WeiChao Wu
·
YOU?
·
· 2025
· Open Access
·
· DOI: https://doi.org/10.1371/journal.pone.0335053
YOU?
·
· 2025
· Open Access
·
· DOI: https://doi.org/10.1371/journal.pone.0335053
Microbial communities inhabiting intertidal sediment show diverse metabolisms to adapt to hydrodynamic conditions. However, the priming effect of exogenous organic matter on microbial metabolic fluxes remains poorly understood. Here we investigated microbial intercellular activities in surface sandy intertidal sediment (0–5 cm depth, from the Nanhui tidal flat, East China Sea) under anoxic conditions by incubating with position-specific 13 C labelled glucose isotopologues. Elevated production of 13 C-CO 2 and phospholipid-derived fatty acids (PLFAs) was observed after 96-hour incubation, suggesting a positive priming effect on both catabolic and anabolic activities. The different incorporations of 13 C-label from glucose isotopologues into CO 2 and PLFAs reveal distinct intracellular carbon fluxes through the central metabolic network. Specifically, microbial communities preferentially utilize the Embden-Meyerhof-Parnas (EMP) pathway (62% flux), followed by the Pentose Phosphate (PP, 25%) and Entner-Doudoroff (ED, 13%) pathways. These flux distributions closely mirror their corresponding functional genome proportion (55% EMP, 26% PP, 20% ED), suggesting a metabolic balance between energy yield and enzyme cost across glycolytic routes. Furthermore, metabolic flux analysis based on 13 C-PLFA profiles highlights diverse metabolic strategies among different microbial taxa, primarily involving the EMP, ED and tricarboxylic acid pathways. This underscores the dual importance of energy production and carbon allocation for biomass synthesis. Given the high protein cost for the EMP pathway, energy acquisition may be prioritized by anaerobes to withstand the fluctuating conditions. Our results suggest that microbial interactions with intercellular networks may play a critical role in facilitating the priming and subsequent degradation of sedimentary organic matter.
Related Topics
Concepts
Pentose phosphate pathway
Anabolism
Biology
Intertidal zone
Metabolic pathway
Flux (metallurgy)
Microbial population biology
Organic matter
Metabolic flux analysis
Sediment
Anoxic waters
Ecology
Catabolism
Environmental chemistry
Carbon cycle
Citric acid cycle
Propionate
Metabolism
Biochemistry
Microbial metabolism
Chemistry
Intracellular
Glycolysis
Autotroph
Metabolic network
Glucose uptake
Dissolved organic carbon
Biomass (ecology)
Microcosm
Respiration
Carbohydrate metabolism
Total organic carbon
Metadata
- Type
- article
- Language
- en
- Landing Page
- https://doi.org/10.1371/journal.pone.0335053
- OA Status
- gold
- References
- 52
- OpenAlex ID
- https://openalex.org/W7106677086
All OpenAlex metadata
Raw OpenAlex JSON
- OpenAlex ID
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https://openalex.org/W7106677086Canonical identifier for this work in OpenAlex
- DOI
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https://doi.org/10.1371/journal.pone.0335053Digital Object Identifier
- Title
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Glucose priming effect on microbial intercellular metabolic flux diversity in a marine intertidal sedimentWork title
- Type
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articleOpenAlex work type
- Language
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enPrimary language
- Publication year
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2025Year of publication
- Publication date
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2025-11-26Full publication date if available
- Authors
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Tao Ji, ZhiAo Xu, Lihong Wen, Yuxue Yang, Yue Wu, Xueqin Zhao, Ruilian Yao, Ru-Long Liu, Yunping Xu, WeiChao WuList of authors in order
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-
https://doi.org/10.1371/journal.pone.0335053Publisher landing page
- Open access
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YesWhether a free full text is available
- OA status
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goldOpen access status per OpenAlex
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https://doi.org/10.1371/journal.pone.0335053Direct OA link when available
- Concepts
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Pentose phosphate pathway, Anabolism, Biology, Intertidal zone, Metabolic pathway, Flux (metallurgy), Microbial population biology, Organic matter, Metabolic flux analysis, Sediment, Anoxic waters, Ecology, Catabolism, Environmental chemistry, Carbon cycle, Citric acid cycle, Propionate, Metabolism, Biochemistry, Microbial metabolism, Chemistry, Intracellular, Glycolysis, Autotroph, Metabolic network, Glucose uptake, Dissolved organic carbon, Biomass (ecology), Microcosm, Respiration, Carbohydrate metabolism, Total organic carbonTop concepts (fields/topics) attached by OpenAlex
- Cited by
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0Total citation count in OpenAlex
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| referenced_works_count | 52 |
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| abstract_inverted_index.C | 58 |
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| abstract_inverted_index.13 | 57, 65, 93, 171 |
| abstract_inverted_index.CO | 99 |
| abstract_inverted_index.ED | 186 |
| abstract_inverted_index.be | 217 |
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| abstract_inverted_index.we | 29 |
| abstract_inverted_index.20% | 150 |
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| abstract_inverted_index.Our | 226 |
| abstract_inverted_index.PP, | 149 |
| abstract_inverted_index.The | 89 |
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| abstract_inverted_index.EMP, | 147, 185 |
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| abstract_inverted_index.Here | 28 |
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| abstract_inverted_index.(0–5 | 39 |
| abstract_inverted_index.C-PLFA | 172 |
| abstract_inverted_index.Nanhui | 44 |
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| abstract_inverted_index.carbon | 106, 200 |
| abstract_inverted_index.depth, | 41 |
| abstract_inverted_index.effect | 16, 82 |
| abstract_inverted_index.energy | 157, 197, 214 |
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| abstract_inverted_index.fluxes | 24, 107 |
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| abstract_inverted_index.reveal | 103 |
| abstract_inverted_index.(PLFAs) | 72 |
| abstract_inverted_index.96-hour | 76 |
| abstract_inverted_index.C-label | 94 |
| abstract_inverted_index.Pentose | 127 |
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| abstract_inverted_index.Elevated | 62 |
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