Nitrite-driven anaerobic ethane oxidation

IF 14 1区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Environmental Science and Ecotechnology Pub Date : 2024-06-13 DOI:10.1016/j.ese.2024.100438

Cheng-Cheng Dang , Yin-Zhu Jin , Xin Tan , Wen-Bo Nie , Yang Lu , Bing-Feng Liu , De-Feng Xing , Nan-Qi Ren , Guo-Jun Xie

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Abstract

Ethane, the second most abundant gaseous hydrocarbon in vast anoxic environments, is an overlooked greenhouse gas. Microbial anaerobic oxidation of ethane can be driven by available electron acceptors such as sulfate and nitrate. However, despite nitrite being a more thermodynamically feasible electron acceptor than sulfate or nitrate, little is known about nitrite-driven anaerobic ethane oxidation. In this study, a microbial culture capable of nitrite-driven anaerobic ethane oxidation was enriched through the long-term operation of a nitrite-and-ethane-fed bioreactor. During continuous operation, the nitrite removal rate and the theoretical ethane oxidation rate remained stable at approximately 25.0 mg NO₂^–N L⁻¹ d⁻¹ and 11.48 mg C₂H₆ L⁻¹ d⁻¹, respectively. Batch tests demonstrated that ethane is essential for nitrite removal in this microbial culture. Metabolic function analysis revealed that a species affiliated with a novel genus within the family Rhodocyclaceae, designated as 'Candidatus Alkanivoras nitrosoreducens', may perform the nitrite-driven anaerobic ethane oxidation. In the proposed metabolic model, despite the absence of known genes for ethane conversion to ethyl-succinate and succinate-CoA ligase, 'Ca. A. nitrosoreducens' encodes a prospective fumarate addition pathway for anaerobic ethane oxidation and a complete denitrification pathway for nitrite reduction to nitrogen. These findings advance our understanding of nitrite-driven anaerobic ethane oxidation, highlighting the previously overlooked impact of anaerobic ethane oxidation in natural ecosystems.

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亚硝酸盐驱动的厌氧乙烷氧化作用

乙烷是广阔缺氧环境中含量第二高的气态碳氢化合物，是一种被忽视的温室气体。可用的电子受体（如硫酸盐和硝酸盐）可推动乙烷的微生物厌氧氧化。然而，尽管亚硝酸盐是热力学上比硫酸盐或硝酸盐更可行的电子受体，但人们对亚硝酸盐驱动的厌氧乙烷氧化却知之甚少。在本研究中，通过长期运行亚硝酸盐和乙烷喂养生物反应器，丰富了能够进行亚硝酸盐驱动厌氧乙烷氧化的微生物培养。在连续运行期间，亚硝酸盐去除率和理论乙烷氧化率分别稳定在约 25.0 mg NO2-N L-1 d-1 和 11.48 mg C2H6 L-1 d-1。批量试验表明，乙烷对该微生物培养物去除亚硝酸盐至关重要。代谢功能分析显示，一种隶属于 Rhodocyclaceae 家族中一个新属（命名为 "Candidatus Alkanivoras nitrosoreducens"）的物种可能会进行亚硝酸盐驱动的厌氧乙烷氧化。在所提出的代谢模型中，尽管没有已知的乙烷转化为乙基琥珀酸和琥珀酸-CoA 连接酶的基因，但'Ca.A.nitrosoreducens'编码了一条用于厌氧乙烷氧化的富马酸添加途径和一条用于将亚硝酸盐还原为氮的完整反硝化途径。这些发现增进了我们对亚硝酸盐驱动的厌氧乙烷氧化作用的了解，凸显了厌氧乙烷氧化作用在自然生态系统中的影响以前曾被忽视。

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来源期刊

Environmental Science and Ecotechnology Multiple-

CiteScore

20.40

自引率

6.30%

发文量

审稿时长

18 days

期刊介绍： Environmental Science & Ecotechnology (ESE) is an international, open-access journal publishing original research in environmental science, engineering, ecotechnology, and related fields. Authors publishing in ESE can immediately, permanently, and freely share their work. They have license options and retain copyright. Published by Elsevier, ESE is co-organized by the Chinese Society for Environmental Sciences, Harbin Institute of Technology, and the Chinese Research Academy of Environmental Sciences, under the supervision of the China Association for Science and Technology.

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