Slicer 的生成：人 Argonaute-1 的激活。

The making of a slicer: activation of human Argonaute-1.

机构信息

W.M. Keck Structural Biology Laboratory, Cold Spring Harbor Laboratory, 1 Bungtown Road, Cold Spring Harbor, NY 11724, USA.

出版信息

Cell Rep. 2013 Jun 27;3(6):1901-9. doi: 10.1016/j.celrep.2013.05.033. Epub 2013 Jun 6.

DOI:10.1016/j.celrep.2013.05.033

PMID:23746446

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3769929/

Abstract

Argonautes are the central protein component in small RNA silencing pathways. Of the four human Argonautes (hAgo1-hAgo4) only hAgo2 is an active slicer. We determined the structure of hAgo1 bound to endogenous copurified RNAs to 1.75 Å resolution and hAgo1 loaded with let-7 microRNA to 2.1 Å. Both structures are strikingly similar to the structures of hAgo2. A conserved catalytic tetrad within the PIWI domain of hAgo2 is required for its slicing activity. Completion of the tetrad, combined with a mutation on a loop adjacent to the active site of hAgo1, results in slicer activity that is substantially enhanced by swapping in the N domain of hAgo2. hAgo3, with an intact tetrad, becomes an active slicer by swapping the N domain of hAgo2 without additional mutations. Intriguingly, the elements that make Argonaute an active slicer involve a sophisticated interplay between the active site and more distant regions of the enzyme.

摘要

Argonautes 是小 RNA 沉默途径中的核心蛋白成分。在四种人类 Argonautes（hAgo1-hAgo4）中，只有 hAgo2 是有活性的核酸内切酶。我们将与人内源性共纯化 RNA 结合的 hAgo1 结构解析至 1.75Å分辨率，将负载 let-7 微 RNA 的 hAgo1 结构解析至 2.1Å分辨率。这两种结构与 hAgo2 的结构非常相似。hAgo2 的 PIWI 结构域内保守的催化四联体对于其核酸内切酶活性是必需的。四联体的完成，加上与 hAgo1 活性位点相邻的环上的突变，导致通过交换 hAgo2 的 N 结构域，核酸内切酶活性得到显著增强。hAgo3 具有完整的四联体，通过交换 hAgo2 的 N 结构域而无需额外突变即可成为有活性的核酸内切酶。有趣的是，使 Argonaute 成为有活性的核酸内切酶的元素涉及酶的活性位点和更远区域之间的复杂相互作用。

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