不断扩大的阿斯加德古菌使人们对生命之树和真核生成有了新的认识。

IF 4.5 Q1 MICROBIOLOGY mLife Pub Date : 2022-12-18 eCollection Date: 2022-12-01 DOI:10.1002/mlf2.12048
Zhichao Zhou, Yang Liu, Karthik Anantharaman, Meng Li
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引用次数: 0

摘要

将生命树上的生物划分为三维(3D)树或二维(2D)树一直以来都存在争议。自从卡尔-沃斯(Carl Woese)于 1977 年以 16S 核糖体 RNA 序列为进化标志发现古细菌以来,我们不仅对古细菌日益增长的多样性,而且对不同生物系之间的进化关系有了更深入的了解。在此,我们从这个角度总结了古细菌多样性的进展和生命之树概念的变化。同时,我们提供了基于基因组学/生理学发现作为真核生物近亲的阿斯加德古菌系的最新进展。此外,我们还提出了未来研究的三个主要方向:探索 "下一个 "最近的真核生物亲缘关系;从基因组学和生理学两方面破译古细菌真核标志蛋白的功能和真核发生;了解水平基因转移、病毒和移动元素在真核发生中的作用。
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The expanding Asgard archaea invoke novel insights into Tree of Life and eukaryogenesis.

The division of organisms on the Tree of Life into either a three-domain (3D) tree or a two-domain (2D) tree has been disputed for a long time. Ever since the discovery of Archaea by Carl Woese in 1977 using 16S ribosomal RNA sequence as the evolutionary marker, there has been a great advance in our knowledge of not only the growing diversity of Archaea but also the evolutionary relationships between different lineages of living organisms. Here, we present this perspective to summarize the progress of archaeal diversity and changing notion of the Tree of Life. Meanwhile, we provide the latest progress in genomics/physiology-based discovery of Asgard archaeal lineages as the closest relative of Eukaryotes. Furthermore, we propose three major directions for future research on exploring the "next one" closest Eukaryote relative, deciphering the function of archaeal eukaryotic signature proteins and eukaryogenesis from both genomic and physiological aspects, and understanding the roles of horizontal gene transfer, viruses, and mobile elements in eukaryogenesis.

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