全球缺氧区主要厌氧菌的年龄、新陈代谢和潜在来源

IF 5.1 Q1 ECOLOGY ISME communications Pub Date : 2024-04-22 DOI:10.1093/ismeco/ycae060
Rui Zhao, Irene H Zhang, A. Jayakumar, B. Ward, A. R. Babbin
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摘要

栖息在缺氧区(ODZ)的氨氧化细菌是全球海洋中介导固定氮损失的一个主要功能群。然而,有关缺氧区厌氧菌的多样性、广泛代谢、起源和适应机制等许多基本问题仍未得到解决。在这里,我们报告了两个新的元基因组组装的隶属于Scalindua属的厌氧细菌基因组,它们代表了全球ODZ中的大部分(如果不是全部)厌氧细菌。元基因组读取招募以及与历史数据的比较表明,它们在所有三个主要 ODZ 中都普遍存在。除了核心的氨氧化代谢之外,这两种生物都含有氰酶,其中更主要的一种编码脲酶,这表明大多数 ODZ 氨氧化细菌除了利用氨之外,还能利用氰酸盐和尿素。分子钟分析表明,这些细菌进化成 ODZ 的时间不会早于 3.1 亿年前,即最早的现代型 ODZ 出现后约 10 亿年。在底栖沉积物中也发现了不同的 ODZ Scalindua 菌株,最早的 ODZ Scalindua 很可能来自底栖。与同一支系的底栖菌株相比,ODZ Scalindua独特地编码了尿素利用基因,但丢失了与生长停滞、鞭毛合成和趋化有关的基因,这可能是为了适应在全球ODZ水域中的生长。我们的发现扩展了控制全球氮预算的细菌的已知代谢和进化历史。
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Age, metabolisms, and potential origin of dominant anammox bacteria in the global oxygen deficient zones
Anammox bacteria inhabiting oxygen deficient zones (ODZs) are a major functional group mediating fixed nitrogen loss in the global ocean. However, many basic questions regarding the diversity, broad metabolisms, origin, and adaptive mechanisms of ODZ anammox bacteria remain unaddressed. Here we report two novel metagenome-assembled genomes of anammox bacteria affiliated with the Scalindua genus, which represent most, if not all, of the anammox bacteria in the global ODZs. Metagenomic read recruiting and comparison with historical data show that they are ubiquitously present in all three major ODZs. Beyond the core anammox metabolism, both organisms contain cyanase and the more dominant one encodes a urease, indicating most ODZ anammox bacteria can utilize cyanate and urea in addition to ammonium. Molecular clock analysis suggests that the evolutionary radiation of these bacteria into ODZs occurred no earlier than 310 million years ago, about one billion years after the emergence of the earliest modern-type ODZs. Different strains of the ODZ Scalindua species are also found in benthic sediments, and the first ODZ Scalindua likely derived from the benthos. Compared to benthic strains of the same clade, ODZ Scalindua uniquely encode genes for urea utilization but lost genes related to growth arrest, flagellum synthesis, and chemotaxis, presumably for adaptation to thrive in the global ODZ waters. Our findings expand the known metabolism and evolutionary history of the bacteria controlling the global nitrogen budget.
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