RNase III 酶的丝氨酸 300 或丝氨酸 302 磷酸化是其核定位所必需的。

Phosphorylation of the RNase III enzyme Drosha at Serine300 or Serine302 is required for its nuclear localization.

机构信息

Laboratory of Retrovirology, Division of Infectious Diseases, Department of Medicine, Warren Alpert Medical School of Brown University, Providence, RI 02903, USA.

出版信息

Nucleic Acids Res. 2010 Oct;38(19):6610-9. doi: 10.1093/nar/gkq547. Epub 2010 Jun 16.

DOI:10.1093/nar/gkq547

PMID:20554852

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2965249/

Abstract

The RNaseIII enzyme Drosha plays a pivotal role in microRNA (miRNA) biogenesis by cleaving primary miRNA transcripts to generate precursor miRNA in the nucleus. The RNA binding and enzymatic domains of Drosha have been characterized and are on its C-terminus. Its N-terminus harbors a nuclear localization signal. Using a series of truncated Drosha constructs, we narrowed down the segment responsible for nuclear translocation to a domain between aa 270 and aa 390. We further identified two phosphorylation sites at Serine300 (S300) and Serine302 (S302) by mass spectrometric analysis. Double mutations of S→A at S300 and S302 completely disrupted nuclear localization. Single mutation of S→A at S300 or S302, however, had no effect on nuclear localization indicating that phosphorylation at either site is sufficient to locate Drosha to the nucleus. Furthermore, mimicking phosphorylation status by mutating S→E at S300 and/or S→D at S302 restored nuclear localization. Our findings add a further layer of complexity to the molecular anatomy of Drosha as it relates to miRNA biogenesis.

摘要

RNaseIII 酶 Drosha 在 microRNA（miRNA）生物发生中起着关键作用，通过切割初级 miRNA 转录本在核内产生前体 miRNA。Drosha 的 RNA 结合和酶结构域已被表征，位于其 C 末端。其 N 末端含有核定位信号。通过一系列截断的 Drosha 构建体，我们将负责核易位的片段缩小到 aa 270 和 aa 390 之间的一个结构域。我们通过质谱分析进一步鉴定了两个磷酸化位点丝氨酸 300（S300）和丝氨酸 302（S302）。S300 和 S302 处 S→A 的双突变完全破坏了核定位。然而，S300 或 S302 处 S→A 的单突变对核定位没有影响，表明任一位点的磷酸化足以将 Drosha 定位到核内。此外，通过将 S300 处的 S→E 突变和/或 S302 处的 S→D 突变模拟磷酸化状态，恢复了核定位。我们的发现为 Drosha 与 miRNA 生物发生相关的分子解剖学增加了一个新的复杂性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4261/2965249/8076f04c0221/gkq547f1.jpg

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RNase III 酶的丝氨酸 300 或丝氨酸 302 磷酸化是其核定位所必需的。

Phosphorylation of the RNase III enzyme Drosha at Serine300 or Serine302 is required for its nuclear localization.

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