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多样化产生反转录元件中逆转录的RNA调控

RNA control of reverse transcription in a diversity-generating retroelement.

作者信息

Handa Sumit, Biswas Tapan, Chakraborty Jeet, Ghosh Gourisankar, Paul Blair G, Ghosh Partho

机构信息

Department of Chemistry and Biochemistry, University of California San Diego, La Jolla, CA, USA.

10X Genomics, Pleasanton, CA, USA.

出版信息

Nature. 2025 Feb;638(8052):1122-1129. doi: 10.1038/s41586-024-08405-w. Epub 2025 Jan 8.

DOI:10.1038/s41586-024-08405-w
PMID:39779855
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11995886/
Abstract

Diversity-generating retroelements (DGRs) create massive protein sequence variation (up to 10) in ecologically diverse microorganisms. A recent survey identified around 31,000 DGRs from more than 1,500 bacterial and archaeal genera, constituting more than 90 environment types. DGRs are especially enriched in the human gut microbiome and nano-sized microorganisms that seem to comprise most microbial life and maintain DGRs despite reduced genomes. DGRs are also implicated in the emergence of multicellularity. Variation occurs during reverse transcription of a protein-encoding RNA template coupled to misincorporation at adenosines. In the prototypical Bordetella bacteriophage DGR, the template must be surrounded by upstream and downstream RNA segments for complementary DNA synthesis to be carried out by a complex of the DGR reverse transcriptase bRT and associated protein Avd. The function of the surrounding RNA was unknown. Here we show through cryogenic electron microscopy that this RNA envelops bRT and lies over the barrel-shaped Avd, forming an intimate ribonucleoprotein. An abundance of essential interactions in the ribonucleoprotein precisely position an RNA homoduplex in the bRT active site for initiation of reverse transcription. Our results explain how the surrounding RNA primes complementary DNA synthesis, promotes processivity, terminates polymerization and strictly limits mutagenesis to specific proteins through mechanisms that are probably conserved in DGRs belonging to distant taxa.

摘要

多样性产生逆转录元件(DGRs)在生态多样的微生物中创造了大量的蛋白质序列变异(高达10种)。最近的一项调查从1500多个细菌和古菌属中鉴定出约31000个DGRs,涵盖了90多种环境类型。DGRs在人类肠道微生物群和纳米级微生物中尤其丰富,这些微生物似乎构成了大多数微生物生命形式,并且尽管基因组缩小但仍保留着DGRs。DGRs还与多细胞性的出现有关。变异发生在蛋白质编码RNA模板的逆转录过程中,同时伴随着腺苷处的错误掺入。在典型的博德特氏菌噬菌体DGR中,模板必须被上游和下游RNA片段包围,以便由DGR逆转录酶bRT和相关蛋白Avd组成的复合物进行互补DNA合成。周围RNA的功能尚不清楚。在这里,我们通过低温电子显微镜显示,这种RNA包裹着bRT并位于桶状的Avd上方,形成了一个紧密的核糖核蛋白。核糖核蛋白中大量的关键相互作用将一个RNA同型双链体精确地定位在bRT活性位点,以启动逆转录。我们的结果解释了周围RNA如何引发互补DNA合成、促进持续性、终止聚合反应,并通过可能在远缘分类群的DGR中保守的机制将诱变严格限制在特定蛋白质上。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7da0/11995886/1f118bba201a/nihms-2062589-f0005.jpg
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