Structure of an archaeal ribosome reveals a divergent active site and hibernation factor

IF 20.5 1区生物学 Q1 MICROBIOLOGY

Nature Microbiology Pub Date : 2025-07-17 DOI:10.1038/s41564-025-02065-w

Amos J. Nissley, Yekaterina Shulgina, Roan W. Kivimae, Blake E. Downing, Petar I. Penev, Jillian F. Banfield, Dipti D. Nayak, Jamie H. D. Cate

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Abstract

Ribosomes translate mRNA into protein. Despite divergence in ribosome structure over the course of evolution, the catalytic site, known as the peptidyl transferase centre (PTC), is thought to be nearly universally conserved. Here we identify clades of archaea that have highly divergent ribosomal RNA sequences in the PTC. To understand how these PTC sequences fold, we determined cryo-EM structures of the 70S and 50S ribosomes to 2.4 Å and 2 Å, respectively, from the hyperthermophilic archaeon Pyrobaculum calidifontis. PTC sequence variation leads to the rearrangement of key base triples, and differences between archaeal and bacterial ribosomal proteins enable sequence variation in archaeal PTCs. Finally, we identify an archaeal ribosome hibernation factor, Dri, that differs from known bacterial and eukaryotic hibernation factors and is found in multiple archaeal phyla. Overall, this work identifies factors that regulate ribosome function in archaea and reveals a larger diversity of the most ancient sequences in the ribosome.

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古细菌核糖体的结构揭示了不同的活性位点和冬眠因子

核糖体将mRNA翻译成蛋白质。尽管在进化过程中核糖体结构存在差异，但催化位点，即肽基转移酶中心（PTC），被认为是几乎普遍保守的。在这里，我们鉴定出古生菌在PTC中具有高度不同的核糖体RNA序列的分支。为了了解这些PTC序列是如何折叠的，我们测定了来自超嗜热古菌caldifontis的70S和50S核糖体的低温电镜结构，分别为2.4 Å和2 Å。PTC序列的变异导致关键碱基三组重排，而古生菌与细菌核糖体蛋白的差异导致了古生菌PTC序列的变异。最后，我们鉴定了一种不同于已知细菌和真核生物冬眠因子的古细菌核糖体冬眠因子Dri，它存在于多个古细菌门中。总的来说，这项工作确定了调节古生菌核糖体功能的因素，并揭示了核糖体中最古老序列的更大多样性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nature Microbiology Immunology and Microbiology-Microbiology

CiteScore

44.40

自引率

1.10%

发文量

226

期刊介绍： Nature Microbiology aims to cover a comprehensive range of topics related to microorganisms. This includes: Evolution: The journal is interested in exploring the evolutionary aspects of microorganisms. This may include research on their genetic diversity, adaptation, and speciation over time. Physiology and cell biology: Nature Microbiology seeks to understand the functions and characteristics of microorganisms at the cellular and physiological levels. This may involve studying their metabolism, growth patterns, and cellular processes. Interactions: The journal focuses on the interactions microorganisms have with each other, as well as their interactions with hosts or the environment. This encompasses investigations into microbial communities, symbiotic relationships, and microbial responses to different environments. Societal significance: Nature Microbiology recognizes the societal impact of microorganisms and welcomes studies that explore their practical applications. This may include research on microbial diseases, biotechnology, or environmental remediation. In summary, Nature Microbiology is interested in research related to the evolution, physiology and cell biology of microorganisms, their interactions, and their societal relevance.