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本文引用的文献

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Alternative Splicing and Cross-Talk with Light Signaling.可变剪接与光信号的串扰。
Plant Cell Physiol. 2018 Jun 1;59(6):1104-1110. doi: 10.1093/pcp/pcy089.
2
SPF45-related splicing factor for phytochrome signaling promotes photomorphogenesis by regulating pre-mRNA splicing in .SPF45 相关的光信号 splicing 因子通过调节 pre-mRNA 的 splicing 促进光形态建成。
Proc Natl Acad Sci U S A. 2017 Aug 15;114(33):E7018-E7027. doi: 10.1073/pnas.1706379114. Epub 2017 Jul 31.
3
Depletion of Arabidopsis SC35 and SC35-like serine/arginine-rich proteins affects the transcription and splicing of a subset of genes.拟南芥SC35及类SC35富含丝氨酸/精氨酸蛋白的缺失会影响一部分基因的转录和剪接。
PLoS Genet. 2017 Mar 8;13(3):e1006663. doi: 10.1371/journal.pgen.1006663. eCollection 2017 Mar.
4
Alternative Splicing Substantially Diversifies the Transcriptome during Early Photomorphogenesis and Correlates with the Energy Availability in Arabidopsis.可变剪接在拟南芥早期光形态建成过程中使转录组显著多样化,并与能量可用性相关。
Plant Cell. 2016 Nov;28(11):2715-2734. doi: 10.1105/tpc.16.00508. Epub 2016 Nov 1.
5
CRISPR-Cas9-mediated efficient directed mutagenesis and RAD51-dependent and RAD51-independent gene targeting in the moss Physcomitrella patens.CRISPR-Cas9介导的高效定向诱变以及在小立碗藓中依赖RAD51和不依赖RAD51的基因靶向
Plant Biotechnol J. 2017 Jan;15(1):122-131. doi: 10.1111/pbi.12596. Epub 2016 Jul 22.
6
Genome Editing with CRISPR-Cas9: Can It Get Any Better?使用CRISPR-Cas9进行基因组编辑:它还能更完善吗?
J Genet Genomics. 2016 May 20;43(5):239-50. doi: 10.1016/j.jgg.2016.04.008. Epub 2016 Apr 24.
7
Transcriptome-Wide Identification of RNA Targets of Arabidopsis SERINE/ARGININE-RICH45 Uncovers the Unexpected Roles of This RNA Binding Protein in RNA Processing.拟南芥富含丝氨酸/精氨酸蛋白45的RNA靶标的全转录组鉴定揭示了这种RNA结合蛋白在RNA加工中的意外作用。
Plant Cell. 2015 Dec;27(12):3294-308. doi: 10.1105/tpc.15.00641. Epub 2015 Nov 24.
8
Acute Effects of Light on Alternative Splicing in Light-Grown Plants.光对光生长植物可变剪接的急性影响。
Photochem Photobiol. 2016 Jan-Feb;92(1):126-33. doi: 10.1111/php.12550. Epub 2015 Dec 15.
9
Pre-mRNA Splicing in Plants: In Vivo Functions of RNA-Binding Proteins Implicated in the Splicing Process.植物中的前体mRNA剪接:参与剪接过程的RNA结合蛋白的体内功能
Biomolecules. 2015 Jul 24;5(3):1717-40. doi: 10.3390/biom5031717.
10
Light-activated phytochrome A and B interact with members of the SPA family to promote photomorphogenesis in Arabidopsis by reorganizing the COP1/SPA complex.光激活的光敏色素A和B与SPA家族成员相互作用,通过重组COP1/SPA复合体来促进拟南芥的光形态建成。
Plant Cell. 2015 Jan;27(1):189-201. doi: 10.1105/tpc.114.134775. Epub 2015 Jan 27.

光敏色素通过与 hnRNP 协调作用,通过外显子剪接沉默子来调控可变剪接。

Phytochrome Coordinates with a hnRNP to Regulate Alternative Splicing via an Exonic Splicing Silencer.

机构信息

Institute of Plant and Microbial Biology, Academia Sinica, Taipei 11529, Taiwan.

Molecular and Biological Agricultural Sciences Program, Taiwan International Graduate Program, Chung-Hsing University and Academia Sinica, Taipei 11529, Taiwan.

出版信息

Plant Physiol. 2020 Jan;182(1):243-254. doi: 10.1104/pp.19.00289. Epub 2019 Sep 9.

DOI:10.1104/pp.19.00289
PMID:31501299
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6945828/
Abstract

Plants perceive environmental light conditions and optimize their growth and development accordingly by regulating gene activity at multiple levels. Photoreceptors are important for light sensing and downstream gene regulation. Phytochromes, red/far-red light receptors, are believed to regulate light-responsive alternative splicing, but little is known about the underlying mechanism. Alternative splicing is primarily regulated by transacting factors, such as splicing regulators, and by cis-acting elements in precursor mRNA. In the moss , we show that phytochrome 4 (PpPHY4) directly interacts with a splicing regulator, heterogeneous nuclear ribonucleoprotein F1 (PphnRNP-F1), in the nucleus to regulate light-responsive alternative splicing. RNA sequencing analysis revealed that PpPHY4 and PphnRNP-F1 coregulate 70% of intron retention (IR) events in response to red light. A repetitive GAA motif was identified to be an exonic splicing silencer that controls red light-responsive IR. Biochemical studies indicated that PphnRNP-F1 is recruited by the GAA motif to form RNA-protein complexes. Finally, red light elevates PphnRNP-F1 protein levels via PpPHY4, increasing levels of IR. We propose that PpPHY4 and PphnRNP-F1 regulate alternative splicing through an exonic splicing silencer to control splicing machinery activity in response to light.

摘要

植物通过在多个层面上调节基因活性来感知环境光照条件,并相应地优化其生长和发育。光受体对于光感应和下游基因调控很重要。光敏色素,红光/远红光受体,被认为调节光响应的可变剪接,但对于其潜在机制知之甚少。可变剪接主要受反式作用因子(如剪接调节剂)和前体 mRNA 中的顺式作用元件调节。在苔藓中,我们表明,光敏色素 4(PpPHY4)在核内直接与剪接调节剂异质核核糖核蛋白 F1(PphnRNP-F1)相互作用,以调节光响应的可变剪接。RNA 测序分析显示,PpPHY4 和 PphnRNP-F1 共同调节 70%的红光响应的内含子保留(IR)事件。鉴定出一个重复的 GAA 基序是一个外显子剪接沉默子,它控制红光响应的 IR。生化研究表明,PphnRNP-F1 被 GAA 基序募集形成 RNA-蛋白质复合物。最后,红光通过 PpPHY4 升高 PphnRNP-F1 蛋白水平,增加 IR 水平。我们提出,PpPHY4 和 PphnRNP-F1 通过外显子剪接沉默子调节可变剪接,以响应光来控制剪接机制的活性。