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人类AGO2蛋白通过与微小RNA相互作用与核糖体RNA相连。

Human Argonaute 2 Is Tethered to Ribosomal RNA through MicroRNA Interactions.

作者信息

Atwood Blake L, Woolnough Jessica L, Lefevre Gaelle M, Saint Just Ribeiro Mariana, Felsenfeld Gary, Giles Keith E

机构信息

From the UAB Stem Cell Institute, Department of Biochemistry and Molecular Genetics, University of Alabama at Birmingham, Birmingham, Alabama 35209 and.

Laboratory of Molecular Biology, NIDDK, National Institutes of Health, Bethesda, Maryland.

出版信息

J Biol Chem. 2016 Aug 19;291(34):17919-28. doi: 10.1074/jbc.M116.725051. Epub 2016 Jun 10.

DOI:10.1074/jbc.M116.725051
PMID:27288410
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5016180/
Abstract

The primary role of the RNAi machinery is to promote mRNA degradation within the cytoplasm in a microRNA-dependent manner. However, both Dicer and the Argonaute protein family have expanded roles in gene regulation within the nucleus. To further our understanding of this role, we have identified chromatin binding sites for AGO2 throughout the 45S region of the human rRNA gene. The location of these sites was mirrored by the positions of AGO2 cross-linking sites identified via PAR-CLIP-seq. AGO2 binding to the rRNA within the nucleus was confirmed by RNA immunoprecipitation and quantitative-PCR. To explore a possible mechanism by which AGO2 could be recruited to the rRNA, we identified 1174 regions within the 45S rRNA transcript that have the ability to form a perfect duplex with position 2-6 (seed sequence) of each microRNA expressed in HEK293T cells. Of these potential AGO2 binding sites, 479 occurred within experimentally verified AGO2-rRNA cross-linking sites. The ability of AGO2 to cross-link to rRNA was almost completely lost in a DICER knock-out cell line. The transfection of miR-92a-2-3p into the noDICE cell line facilitated AGO2 cross-linking at a region of the rRNA that has a perfect seed match at positions 3-8, including a single G-U base pair. Knockdown of AGO2 within HEK293T cells causes a slight, but statistically significant increase in the overall rRNA synthesis rate but did not impact the ratio of processing intermediates or the recruitment of the Pol I transcription factor UBTF.

摘要

RNA干扰机制的主要作用是以一种依赖微小RNA的方式促进细胞质内的信使核糖核酸降解。然而,Dicer和AGO蛋白家族在细胞核内的基因调控中都发挥着扩展作用。为了进一步了解这一作用,我们在人类核糖体RNA基因的45S区域内确定了AGO2的染色质结合位点。这些位点的位置与通过PAR-CLIP-seq鉴定的AGO2交联位点的位置相对应。通过RNA免疫沉淀和定量PCR证实了AGO2在细胞核内与核糖体RNA的结合。为了探究AGO2可能被招募到核糖体RNA的机制,我们在45S核糖体RNA转录本中确定了1174个区域,这些区域能够与HEK293T细胞中表达的每个微小RNA的第2 - 6位(种子序列)形成完美的双链体。在这些潜在的AGO2结合位点中,有479个位于经实验验证的AGO2 - 核糖体RNA交联位点内。在DICER基因敲除的细胞系中,AGO2与核糖体RNA交联的能力几乎完全丧失。将miR - 92a - 2 - 3p转染到noDICE细胞系中,促进了AGO2在核糖体RNA的一个区域交联,该区域在第3 - 8位有完美的种子匹配,包括一个G - U碱基对。在HEK293T细胞中敲低AGO2会导致整体核糖体RNA合成速率略有但具有统计学意义的增加,但不影响加工中间体的比例或RNA聚合酶I转录因子UBTF的招募。

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