Organic metabolite uptake by diazotrophs in the North Pacific Ocean.

IF 5.1 Q1 ECOLOGY

ISME communications Pub Date : 2025-05-05 eCollection Date: 2025-01-01 DOI:10.1093/ismeco/ycaf061

Alba Filella, Aurélie Cébron, Benoît Paix, Marine Vallet, Pauline Martinot, Léa Guyomarch, Catherine Guigue, Marc Tedetti, Olivier Grosso, Kendra A Turk-Kubo, Lasse Riemann, Mar Benavides

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Abstract

Dinitrogen (N₂) fixation by diazotrophs supports ocean productivity. Diazotrophs include photoautotrophic cyanobacteria, non-cyanobacterial diazotrophs (NCDs), and the recently discovered N₂-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 ¹³C-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 Crocosphaera and Trichodesmium to NCDs at stations where the N₂-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.

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北太平洋重氮营养体对有机代谢物的吸收。

重氮营养体固定二氮（N₂）支持海洋生产力。重氮营养体包括光自养蓝藻、非蓝藻重氮营养体（NCDs）和最近发现的固氮附生菌。虽然非传染性疾病在海洋中无处不在，但它们的生态和代谢在很大程度上仍然未知。与蓝藻重氮营养菌和共生菌不同，非传染性疾病主要是异养的，依赖于溶解的有机物（DOM）提供碳和能量。然而，传统的DOM修正孵育不允许辨别不同重氮营养体如何使用DOM分子，限制了我们对DOM-重氮营养体相互作用的了解。为了鉴定重氮营养体，我们利用浮游植物培养物中的13c标记DOM对北太平洋微生物群落进行了修饰，并进行了分子表征，揭示了富氮化合物的优势。在添加DOM后，我们观察到在固氮菌丰度相对较低的站点，群落从鳄鱼和Trichodesmium等蓝藻重氮营养体向NCDs转移。通过DNA稳定同位素探测和基因测序，我们发现了多种能够吸收DOM的重氮营养体。我们的研究结果强调了由当地生物地球化学条件塑造的触觉植物硝基质体意想不到的DOM摄取，群落结构的变化以及非传染性疾病中以前未被认识到的渗透行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ISME communications

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