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Auteurs principaux: Ren, Lijuan, Zhu, Ying, Chen, Haiming, He, Dan, Li, Biao, Song, Xingyu, Yang, Yang, Wu, Qinglong L
Format: Artículo científico
Langue:en
Publié: Water research 2026
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41850170/
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author Ren, Lijuan
Zhu, Ying
Chen, Haiming
He, Dan
Li, Biao
Song, Xingyu
Yang, Yang
Wu, Qinglong L
author_facet Ren, Lijuan
Zhu, Ying
Chen, Haiming
He, Dan
Li, Biao
Song, Xingyu
Yang, Yang
Wu, Qinglong L
Ren, Lijuan
Zhu, Ying
Chen, Haiming
He, Dan
Li, Biao
Song, Xingyu
Yang, Yang
Wu, Qinglong L
collection PubMed - marine biology
contents Thermal stress drives coastal microbiome transitions from phototrophic carbon fixation to energy-conserving chemotrophy. Ren, Lijuan Zhu, Ying Chen, Haiming He, Dan Li, Biao Song, Xingyu Yang, Yang Wu, Qinglong L Microbiota Carbon Cycle Phototrophic Processes Photosynthesis Seawater Cyanobacteria Localized thermal discharge offers a natural analog for extreme warming, providing unique insights into how thermal stress shape microbial metabolism in coastal ecosystems. By examining taxonomic and functional dynamics across a pronounced thermal gradient (30-36°C), we identified a distinct transition near 33°C, marked by a systematic decline in phototrophic cyanobacteria (e.g., Synechococcus) and concurrent downregulation of genes involved in oxygenic photosynthesis and the Calvin-Benson-Bassham (CBB) cycle in subtropical Daya Bay. This phototrophic collapse coincided with enrichment of chemoautotrophic (Rhodobacteraceae, Halieaceae) and heterotrophic (SAR11 Ia) lineages, alongside upregulation of energy-efficient chemolithoautotrophic pathways (Wood-Ljungdahl and HP/HB cycle). This metabolic transition near 33°C was reinforced by enhanced energy-generating metabolism (glycolysis, TCA cycle, β-oxidation), dissimilatory nitrogen/sulfur reduction (DNRA: narH/nirB/nirD; DSR: aprA/aprB), and thiosulfate oxidation (SOX: soxY/soxZ/soxD), accelerating nutrient cycling. Microbial adaptation was further reinforced by the upregulation of thermal stress-response genes, including hspR, hspQ, rpoH, and cytochrome oxidases. Collectively, local seawater warming induces a survival strategy prioritizing energy conservation and chemotrophy over phototrophic carbon fixation, reprogramming ecosystem function at the expense of primary production and carbon sequestration while accelerating nitrogen/sulfur turnover. This metabolic transition underscores microbial plasticity but signals vulnerability in critical coastal blue carbon sinks under thermal stress.
format Artículo científico
id pubmed_41850170
institution PubMed
language en
publishDate 2026
publisher Water research
record_format pubmed
spellingShingle Thermal stress drives coastal microbiome transitions from phototrophic carbon fixation to energy-conserving chemotrophy.
Ren, Lijuan
Zhu, Ying
Chen, Haiming
He, Dan
Li, Biao
Song, Xingyu
Yang, Yang
Wu, Qinglong L
Microbiota
Carbon Cycle
Phototrophic Processes
Photosynthesis
Seawater
Cyanobacteria
Thermal stress drives coastal microbiome transitions from phototrophic carbon fixation to energy-conserving chemotrophy. Ren, Lijuan Zhu, Ying Chen, Haiming He, Dan Li, Biao Song, Xingyu Yang, Yang Wu, Qinglong L Microbiota Carbon Cycle Phototrophic Processes Photosynthesis Seawater Cyanobacteria Localized thermal discharge offers a natural analog for extreme warming, providing unique insights into how thermal stress shape microbial metabolism in coastal ecosystems. By examining taxonomic and functional dynamics across a pronounced thermal gradient (30-36°C), we identified a distinct transition near 33°C, marked by a systematic decline in phototrophic cyanobacteria (e.g., Synechococcus) and concurrent downregulation of genes involved in oxygenic photosynthesis and the Calvin-Benson-Bassham (CBB) cycle in subtropical Daya Bay. This phototrophic collapse coincided with enrichment of chemoautotrophic (Rhodobacteraceae, Halieaceae) and heterotrophic (SAR11 Ia) lineages, alongside upregulation of energy-efficient chemolithoautotrophic pathways (Wood-Ljungdahl and HP/HB cycle). This metabolic transition near 33°C was reinforced by enhanced energy-generating metabolism (glycolysis, TCA cycle, β-oxidation), dissimilatory nitrogen/sulfur reduction (DNRA: narH/nirB/nirD; DSR: aprA/aprB), and thiosulfate oxidation (SOX: soxY/soxZ/soxD), accelerating nutrient cycling. Microbial adaptation was further reinforced by the upregulation of thermal stress-response genes, including hspR, hspQ, rpoH, and cytochrome oxidases. Collectively, local seawater warming induces a survival strategy prioritizing energy conservation and chemotrophy over phototrophic carbon fixation, reprogramming ecosystem function at the expense of primary production and carbon sequestration while accelerating nitrogen/sulfur turnover. This metabolic transition underscores microbial plasticity but signals vulnerability in critical coastal blue carbon sinks under thermal stress.
title Thermal stress drives coastal microbiome transitions from phototrophic carbon fixation to energy-conserving chemotrophy.
topic Microbiota
Carbon Cycle
Phototrophic Processes
Photosynthesis
Seawater
Cyanobacteria
url https://pubmed.ncbi.nlm.nih.gov/41850170/