噬菌体触发的反转录从非编码 RNA 组装出毒性重复基因。

Phage-triggered reverse transcription assembles a toxic repetitive gene from a noncoding RNA.

机构信息

Howard Hughes Medical Institute, Massachusetts Institute of Technology, Cambridge, MA 02139, USA.

Broad Institute of MIT and Harvard, Cambridge, MA 02142, USA.

出版信息

Science. 2024 Oct 4;386(6717):eadq3977. doi: 10.1126/science.adq3977.

DOI:10.1126/science.adq3977

PMID:39208082

Abstract

Reverse transcription has frequently been co-opted for cellular functions and in prokaryotes is associated with protection against viral infection, but the underlying mechanisms of defense are generally unknown. Here, we show that in the DRT2 defense system, the reverse transcriptase binds a neighboring pseudoknotted noncoding RNA. Upon bacteriophage infection, a template region of this RNA is reverse transcribed into an array of tandem repeats that reconstitute a promoter and open reading frame, allowing expression of a toxic repetitive protein and an abortive infection response. Biochemical reconstitution of this activity and cryo-electron microscopy provide a molecular basis for repeat synthesis. Gene synthesis from a noncoding RNA is a previously unknown mode of genetic regulation in prokaryotes.

摘要

逆转录经常被用于细胞功能，在原核生物中与抵抗病毒感染有关，但防御的潜在机制通常是未知的。在这里，我们表明在 DRT2 防御系统中，逆转录酶结合了相邻的假结非编码 RNA。在噬菌体感染后，该 RNA 的一个模板区域被逆转录成一系列串联重复序列，重新构成一个启动子和开放阅读框，允许表达一种毒性重复蛋白和一个流产感染反应。这种活性的生化重建和低温电子显微镜为重复合成提供了分子基础。从非编码 RNA 进行基因合成是原核生物中一种以前未知的遗传调控模式。

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噬菌体触发的反转录从非编码 RNA 组装出毒性重复基因。

Phage-triggered reverse transcription assembles a toxic repetitive gene from a noncoding RNA.

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