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CRN-5 和 Rrp46 的结构和生化特性:参与细胞凋亡 DNA 降解的外切体成分。

Structural and biochemical characterization of CRN-5 and Rrp46: an exosome component participating in apoptotic DNA degradation.

机构信息

Graduate Institute of Biochemistry and Molecular Biology, National Taiwan University, Taipei, 10617 Taiwan, Republic of China.

出版信息

RNA. 2010 Sep;16(9):1748-59. doi: 10.1261/rna.2180810. Epub 2010 Jul 21.

DOI:10.1261/rna.2180810
PMID:20660080
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2924534/
Abstract

Rrp46 was first identified as a protein component of the eukaryotic exosome, a protein complex involved in 3' processing of RNA during RNA turnover and surveillance. The Rrp46 homolog, CRN-5, was subsequently characterized as a cell death-related nuclease, participating in DNA fragmentation during apoptosis in Caenorhabditis elegans. Here we report the crystal structures of CRN-5 and rice Rrp46 (oRrp46) at a resolution of 3.9 A and 2.0 A, respectively. We found that recombinant human Rrp46 (hRrp46), oRrp46, and CRN-5 are homodimers, and that endogenous hRrp46 and oRrp46 also form homodimers in a cellular environment, in addition to their association with a protein complex. Dimeric oRrp46 had both phosphorolytic RNase and hydrolytic DNase activities, whereas hRrp46 and CRN-5 bound to DNA without detectable nuclease activity. Site-directed mutagenesis in oRrp46 abolished either its DNase (E160Q) or RNase (K75E/Q76E) activities, confirming the critical importance of these residues in catalysis or substrate binding. Moreover, CRN-5 directly interacted with the apoptotic nuclease CRN-4 and enhanced the DNase activity of CRN-4, suggesting that CRN-5 cooperates with CRN-4 in apoptotic DNA degradation. Taken together all these results strongly suggest that Rrp46 forms a homodimer separately from exosome complexes and, depending on species, is either a structural or catalytic component of the machinery that cleaves DNA during apoptosis.

摘要

Rrp46 最初被鉴定为真核外切体的蛋白质成分,该蛋白复合物参与 RNA 周转和监测过程中 RNA 的 3'加工。随后,Rrp46 的同源物 CRN-5 被表征为与细胞死亡相关的核酸内切酶,参与秀丽隐杆线虫凋亡过程中的 DNA 片段化。在此,我们分别以 3.9Å 和 2.0Å 的分辨率报道了 CRN-5 和水稻 Rrp46(oRrp46)的晶体结构。我们发现重组人 Rrp46(hRrp46)、oRrp46 和 CRN-5 均为同源二聚体,并且内源性 hRrp46 和 oRrp46 除了与蛋白复合物结合外,在细胞环境中也形成同源二聚体。二聚体 oRrp46 具有磷酸解 RNA 酶和水解 DNA 酶活性,而 hRrp46 和 CRN-5 与 DNA 结合时没有检测到核酸酶活性。oRrp46 的定点突变使其 DNA 酶(E160Q)或 RNA 酶(K75E/Q76E)活性丧失,证实这些残基对催化或底物结合至关重要。此外,CRN-5 直接与凋亡核酸内切酶 CRN-4 相互作用,并增强了 CRN-4 的 DNA 酶活性,表明 CRN-5 在凋亡 DNA 降解过程中与 CRN-4 合作。总之,所有这些结果强烈表明 Rrp46 与外切体复合物分开形成同源二聚体,并且根据物种的不同,它要么是在凋亡过程中切割 DNA 的机器的结构或催化组成部分。

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