Projecting global biological N2 fixation under climate warming across land and ocean.

IF 14 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Trends in Microbiology Pub Date : 2024-06-01 Epub Date: 2024-01-22 DOI:10.1016/j.tim.2023.12.007
Curtis Deutsch, Keisuke Inomura, Ya-Wei Luo, Ying-Ping Wang
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Abstract

Biological N2 fixation sustains the global inventory of nitrogenous nutrients essential for the productivity of terrestrial and marine ecosystems. Like most metabolic processes, rates of biological N2 fixation vary strongly with temperature, making it sensitive to climate change, but a global projection across land and ocean is lacking. Here we use compilations of field and laboratory measurements to reveal a relationship between N2 fixation rates and temperature that is similar in both domains despite large taxonomic and environmental differences. Rates of N2 fixation increase gradually to a thermal optimum around ~25°C, and decline more rapidly toward a thermal maximum, which is lower in the ocean than on land. In both realms, the observed temperature sensitivities imply that climate warming this century could decrease N2 fixation rates by ~50% in the tropics while increasing rates by ~50% in higher latitudes. We propose a conceptual framework for understanding the physiological and ecological mechanisms that underpin and modulate the observed temperature dependence of global N2 fixation rates, facilitating cross-fertilization of marine and terrestrial research to assess its response to climate change.

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预测气候变暖条件下陆地和海洋的全球生物 N2 固定量。
生物固氮维持着陆地和海洋生态系统生产力所必需的全球氮营养物质库存。与大多数新陈代谢过程一样,生物固氮的速率随温度的变化而变化,因此对气候变化非常敏感,但目前还缺乏对陆地和海洋的全球预测。在这里,我们通过对野外和实验室测量数据的汇编,揭示了氮固定率与温度之间的关系,尽管在分类学和环境方面存在巨大差异,但这两个领域的氮固定率与温度之间的关系是相似的。N2固定率在约25°C时逐渐升高到最佳温度,在达到最高温度时则迅速下降,海洋中的最高温度低于陆地。在这两个领域中,观测到的温度敏感性意味着,本世纪气候变暖可能会使热带地区的氮固定率下降约 50%,而使高纬度地区的氮固定率上升约 50%。我们提出了一个概念框架,用于理解支撑和调节所观测到的全球 N2 固定率的温度依赖性的生理和生态机制,促进海洋和陆地研究的交叉融合,以评估其对气候变化的响应。
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来源期刊
Trends in Microbiology
Trends in Microbiology 生物-生化与分子生物学
CiteScore
25.30
自引率
0.60%
发文量
193
审稿时长
6-12 weeks
期刊介绍: Trends in Microbiology serves as a comprehensive, multidisciplinary forum for discussing various aspects of microbiology, spanning cell biology, immunology, genetics, evolution, virology, bacteriology, protozoology, and mycology. In the rapidly evolving field of microbiology, technological advancements, especially in genome sequencing, impact prokaryote biology from pathogens to extremophiles, influencing developments in drugs, vaccines, and industrial enzyme research.
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