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外显子-外显子连接复合体在活细胞中的组装与移动性。

Assembly and mobility of exon-exon junction complexes in living cells.

作者信息

Schmidt Ute, Im Kang-Bin, Benzing Carola, Janjetovic Snjezana, Rippe Karsten, Lichter Peter, Wachsmuth Malte

机构信息

Division of Molecular Genetics, Deutsches Krebsforschungszentrum, 69120 Heidelberg, Germany.

出版信息

RNA. 2009 May;15(5):862-76. doi: 10.1261/rna.1387009. Epub 2009 Mar 26.

DOI:10.1261/rna.1387009
PMID:19324961
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2673070/
Abstract

The exon-exon junction complex (EJC) forms via association of proteins during splicing of mRNA in a defined manner. Its organization provides a link between biogenesis, nuclear export, and translation of the transcripts. The EJC proteins accumulate in nuclear speckles alongside most other splicing-related factors. We followed the establishment of the EJC on mRNA by investigating the mobility and interactions of a representative set of EJC factors in vivo using a complementary analysis with different fluorescence fluctuation microscopy techniques. Our observations are compatible with cotranscriptional binding of the EJC protein UAP56 confirming that it is involved in the initial phase of EJC formation. RNPS1, REF/Aly, Y14/Magoh, and NXF1 showed a reduction in their nuclear mobility when complexed with RNA. They interacted with nuclear speckles, in which both transiently and long-term immobilized factors were identified. The location- and RNA-dependent differences in the mobility between factors of the so-called outer shell and inner core of the EJC suggest a hypothetical model, in which mRNA is retained in speckles when EJC outer-shell factors are missing.

摘要

外显子-外显子连接复合体(EJC)在mRNA剪接过程中通过蛋白质以特定方式结合形成。其结构在转录本的生物合成、核输出和翻译之间建立了联系。EJC蛋白与大多数其他剪接相关因子一起聚集在核斑点中。我们通过使用不同荧光波动显微镜技术的互补分析,研究了一组代表性EJC因子在体内的移动性和相互作用,从而追踪了EJC在mRNA上的形成过程。我们的观察结果与EJC蛋白UAP56的共转录结合相一致,证实它参与了EJC形成的初始阶段。RNPS1、REF/Aly、Y14/Magoh和NXF1与RNA结合时,其核移动性降低。它们与核斑点相互作用,在核斑点中鉴定出了瞬时和长期固定的因子。EJC所谓外壳和内核因子之间移动性的位置和RNA依赖性差异提示了一个假设模型,即当EJC外壳因子缺失时,mRNA会保留在斑点中。

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