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Main Authors: Filella, Alba, Cébron, Aurélie, Paix, Benoît, Vallet, Marine, Martinot, Pauline, Guyomarch, Léa, Guigue, Catherine, Tedetti, Marc, Grosso, Olivier, Turk-Kubo, Kendra A, Riemann, Lasse, Benavides, Mar
Format: Artículo científico
Language:en
Published: ISME communications 2025
Online Access:https://pubmed.ncbi.nlm.nih.gov/40352108/
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author Filella, Alba
Cébron, Aurélie
Paix, Benoît
Vallet, Marine
Martinot, Pauline
Guyomarch, Léa
Guigue, Catherine
Tedetti, Marc
Grosso, Olivier
Turk-Kubo, Kendra A
Riemann, Lasse
Benavides, Mar
author_facet Filella, Alba
Cébron, Aurélie
Paix, Benoît
Vallet, Marine
Martinot, Pauline
Guyomarch, Léa
Guigue, Catherine
Tedetti, Marc
Grosso, Olivier
Turk-Kubo, Kendra A
Riemann, Lasse
Benavides, Mar
Filella, Alba
Cébron, Aurélie
Paix, Benoît
Vallet, Marine
Martinot, Pauline
Guyomarch, Léa
Guigue, Catherine
Tedetti, Marc
Grosso, Olivier
Turk-Kubo, Kendra A
Riemann, Lasse
Benavides, Mar
collection PubMed - marine biology
contents Organic metabolite uptake by diazotrophs in the North Pacific Ocean. Filella, Alba Cébron, Aurélie Paix, Benoît Vallet, Marine Martinot, Pauline Guyomarch, Léa Guigue, Catherine Tedetti, Marc Grosso, Olivier Turk-Kubo, Kendra A Riemann, Lasse Benavides, Mar Dinitrogen (N₂) fixation by diazotrophs supports ocean productivity. Diazotrophs include photoautotrophic cyanobacteria, non-cyanobacterial diazotrophs (NCDs), and the recently discovered N-fixing haptophyte. While NCDs are ubiquitous in the ocean, their ecology and metabolism remain largely unknown. Unlike cyanobacterial diazotrophs and the haptophyte, NCDs are primarily heterotrophic and depend on dissolved organic matter (DOM) for carbon and energy. However, conventional DOM amendment incubations do not allow discerning how different diazotrophs use DOM molecules, limiting our knowledge on DOM-diazotroph interactions. To identify diazotrophs using DOM, we amended North Pacific microbial communities with C-labeled DOM from phytoplankton cultures that was molecularly characterized, revealing the dominance of nitrogen-rich compounds. After DOM additions, we observed a community shift from cyanobacterial diazotrophs like and to NCDs at stations where the N-fixing haptophyte abundance was relatively low. Through DNA stable isotope probing and gene sequencing, we identified diverse diazotrophs capable of taking up DOM. Our findings highlight unexpected DOM uptake by the haptophyte's nitroplast, changes in community structure, and previously unrecognized osmotrophic behavior in NCDs, shaped by local biogeochemical conditions.
format Artículo científico
id pubmed_40352108
institution PubMed
language en
publishDate 2025
publisher ISME communications
record_format pubmed
spellingShingle Organic metabolite uptake by diazotrophs in the North Pacific Ocean.
Filella, Alba
Cébron, Aurélie
Paix, Benoît
Vallet, Marine
Martinot, Pauline
Guyomarch, Léa
Guigue, Catherine
Tedetti, Marc
Grosso, Olivier
Turk-Kubo, Kendra A
Riemann, Lasse
Benavides, Mar
Organic metabolite uptake by diazotrophs in the North Pacific Ocean. Filella, Alba Cébron, Aurélie Paix, Benoît Vallet, Marine Martinot, Pauline Guyomarch, Léa Guigue, Catherine Tedetti, Marc Grosso, Olivier Turk-Kubo, Kendra A Riemann, Lasse Benavides, Mar Dinitrogen (N₂) fixation by diazotrophs supports ocean productivity. Diazotrophs include photoautotrophic cyanobacteria, non-cyanobacterial diazotrophs (NCDs), and the recently discovered N-fixing haptophyte. While NCDs are ubiquitous in the ocean, their ecology and metabolism remain largely unknown. Unlike cyanobacterial diazotrophs and the haptophyte, NCDs are primarily heterotrophic and depend on dissolved organic matter (DOM) for carbon and energy. However, conventional DOM amendment incubations do not allow discerning how different diazotrophs use DOM molecules, limiting our knowledge on DOM-diazotroph interactions. To identify diazotrophs using DOM, we amended North Pacific microbial communities with C-labeled DOM from phytoplankton cultures that was molecularly characterized, revealing the dominance of nitrogen-rich compounds. After DOM additions, we observed a community shift from cyanobacterial diazotrophs like and to NCDs at stations where the N-fixing haptophyte abundance was relatively low. Through DNA stable isotope probing and gene sequencing, we identified diverse diazotrophs capable of taking up DOM. Our findings highlight unexpected DOM uptake by the haptophyte's nitroplast, changes in community structure, and previously unrecognized osmotrophic behavior in NCDs, shaped by local biogeochemical conditions.
title Organic metabolite uptake by diazotrophs in the North Pacific Ocean.
url https://pubmed.ncbi.nlm.nih.gov/40352108/