Aerobic nitrogen cycling in a molybdenum-limited, redox-stratified Mesoproterozoic epeiric sea

IF 4.8 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Earth and Planetary Science Letters Pub Date : 2025-04-25 DOI:10.1016/j.epsl.2025.119369

Geoffrey J. Gilleaudeau , Linda C. Kah , Christopher K. Junium , Ariel D. Anbar

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Abstract

Nitrogen is a critically important element for life on Earth, and its cycling through the ocean-atmosphere system is a biologically mediated process that requires a suite of transition metals as enzyme cofactors. For example, the most common form of nitrogenase (the enzyme that mediates nitrogen fixation by prokaryotes) requires molybdenum and iron as structural components. It has been proposed, however, that ‘alternative nitrogenase’ enzymes may have been important under conditions of expanded euxinia and Mo drawdown that may have characterized parts of the Proterozoic oceans. Furthermore, it has been proposed that bioavailable nitrate was scarce in the Mesoproterozoic oceans, inhibiting the evolution of eukaryotes that lack the ability to fix their own nitrogen. To test these hypotheses, we examined nitrogen isotopes (δ¹⁵N) in black and grey shale of the ∼1.1 Ga Atar and El Mreiti groups, Taoudeni Basin, Mauritania as a proxy for nitrogen cycling in the Mesoproterozoic oceans. These strata were previously investigated for iron speciation and trace metal content, and they record a period of substantial Mo drawdown in a redox-stratified epeiric sea. In the Atar and El Mreiti groups, both shallow epicratonic and deeper pericratonic environments record strongly positive δ¹⁵N values (median = +4.6‰), indicative of an aerobic nitrogen cycle characterized by nitrification and partial denitrification, and thus surface waters that were replete in bioavailable nitrate. Even in the most Mo-limited euxinic environments, positive δ¹⁵N values suggest nitrate-replete surface waters. These results are consistent with a large compilation of δ¹⁵N data from other Mesoproterozoic basins, which collectively do not support the presence of a metal-nitrogen co-limited biosphere in the Mesoproterozoic oceans. Instead, we suggest that nitrogen fixation likely proceeded via Mo-Fe-nitrogenase and nitrate was readily available in the oceans during much of the Mesoproterozoic, with phosphorus acting as the limiting macronutrient on the marine biosphere.

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含钼受限、氧化还原层状中元古代表海中需氧氮循环

氮是地球上生命至关重要的元素，它在海洋-大气系统中的循环是一个生物介导的过程，需要一套过渡金属作为酶辅因子。例如，最常见形式的氮酶（介导原核生物固氮的酶）需要钼和铁作为结构成分。然而，有人提出，“替代氮酶”可能在扩大的氧化菌和Mo减少的条件下是重要的，这可能是元古代海洋的部分特征。此外，有人提出，生物可利用的硝酸盐在中元古代海洋中是稀缺的，这抑制了真核生物的进化，因为真核生物缺乏固定自身氮的能力。为了验证这些假设，我们检测了毛里塔尼亚Taoudeni盆地~ 1.1 Ga Atar和El Mreiti组黑色和灰色页岩中的氮同位素（δ15N），作为中元古代海洋氮循环的代表。这些地层以前被研究过铁的形态和微量金属的含量，它们记录了一个氧化还原层状表海中Mo的大量下降。在Atar和El Mreiti组中，浅层和深层表层环境的δ15N值均为正（中位数= +4.6‰），显示出以硝化和部分反硝化为特征的好氧氮循环，因此地表水体中充满了生物有效态硝酸盐。即使在最受mo限制的富氧环境中，正的δ15N值也表明地表水体充满硝酸盐。这些结果与其他中元古代盆地的大量δ15N数据一致，这些数据总体上不支持中元古代海洋中存在金属-氮共限生物圈。相反，我们认为氮固定可能是通过mo - fe -氮酶进行的，在中元古代的大部分时间里，硝酸盐在海洋中很容易获得，而磷是海洋生物圈的限制性常量营养元素。

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来源期刊

Earth and Planetary Science Letters 地学-地球化学与地球物理

CiteScore

10.30

自引率

5.70%

发文量

475

审稿时长

2.8 months

期刊介绍： Earth and Planetary Science Letters (EPSL) is a leading journal for researchers across the entire Earth and planetary sciences community. It publishes concise, exciting, high-impact articles ("Letters") of broad interest. Its focus is on physical and chemical processes, the evolution and general properties of the Earth and planets - from their deep interiors to their atmospheres. EPSL also includes a Frontiers section, featuring invited high-profile synthesis articles by leading experts on timely topics to bring cutting-edge research to the wider community.