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Literature DB >> 25561518

Genome-wide discovery of human splicing branchpoints.

Tim R Mercer¹, Michael B Clark², Stacey B Andersen³, Marion E Brunck³, Wilfried Haerty⁴, Joanna Crawford⁵, Ryan J Taft⁶, Lars K Nielsen³, Marcel E Dinger¹, John S Mattick⁷.

Abstract

During the splicing reaction, the 5' intron end is joined to the branchpoint nucleotide, selecting the next exon to incorporate into the mature RNA and forming an intron lariat, which is excised. Despite a critical role in gene splicing, the locations and features of human splicing branchpoints are largely unknown. We use exoribonuclease digestion and targeted RNA-sequencing to enrich for sequences that traverse the lariat junction and, by split and inverted alignment, reveal the branchpoint. We identify 59,359 high-confidence human branchpoints in >10,000 genes, providing a first map of splicing branchpoints in the human genome. Branchpoints are predominantly adenosine, highly conserved, and closely distributed to the 3' splice site. Analysis of human branchpoints reveals numerous novel features, including distinct features of branchpoints for alternatively spliced exons and a family of conserved sequence motifs overlapping branchpoints we term B-boxes, which exhibit maximal nucleotide diversity while maintaining interactions with the keto-rich U2 snRNA. Different B-box motifs exhibit divergent usage in vertebrate lineages and associate with other splicing elements and distinct intron-exon architectures, suggesting integration within a broader regulatory splicing code. Lastly, although branchpoints are refractory to common mutational processes and genetic variation, mutations occurring at branchpoint nucleotides are enriched for disease associations.

Entities: Chemical Species

Mesh：

Substances：
RNA Splice Sites

Year: 2015 PMID： 25561518 PMCID： PMC4315302 DOI： 10.1101/gr.182899.114

Source DB: PubMed Journal: Genome Res ISSN： 1088-9051 Impact factor: 9.043

67 in total

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Journal: Mol Cell Date: 2013-09-12 Impact factor: 17.970

7. The Human Gene Mutation Database (HGMD) and its exploitation in the fields of personalized genomics and molecular evolution.

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Journal: Curr Protoc Bioinformatics Date: 2012-09

8. Genome-wide association between branch point properties and alternative splicing.

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Authors: Shane Neph; Jeff Vierstra; Andrew B Stergachis; Alex P Reynolds; Eric Haugen; Benjamin Vernot; Robert E Thurman; Sam John; Richard Sandstrom; Audra K Johnson; Matthew T Maurano; Richard Humbert; Eric Rynes; Hao Wang; Shinny Vong; Kristen Lee; Daniel Bates; Morgan Diegel; Vaughn Roach; Douglas Dunn; Jun Neri; Anthony Schafer; R Scott Hansen; Tanya Kutyavin; Erika Giste; Molly Weaver; Theresa Canfield; Peter Sabo; Miaohua Zhang; Gayathri Balasundaram; Rachel Byron; Michael J MacCoss; Joshua M Akey; M A Bender; Mark Groudine; Rajinder Kaul; John A Stamatoyannopoulos
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Journal: Nucleic Acids Res Date: 2013-11-21 Impact factor: 16.971

98 in total

1. Quantitative gene profiling of long noncoding RNAs with targeted RNA sequencing.

Authors: Michael B Clark; Tim R Mercer; Giovanni Bussotti; Tommaso Leonardi; Katelin R Haynes; Joanna Crawford; Marion E Brunck; Kim-Anh Lê Cao; Gethin P Thomas; Wendy Y Chen; Ryan J Taft; Lars K Nielsen; Anton J Enright; John S Mattick; Marcel E Dinger
Journal: Nat Methods Date: 2015-03-09 Impact factor: 28.547

Review 2. Splicing Factor Mutations in Myelodysplasias: Insights from Spliceosome Structures.

Authors: Jermaine L Jenkins; Clara L Kielkopf
Journal: Trends Genet Date: 2017-03-31 Impact factor: 11.639

Review 3. RNA Splicing and Disease: Animal Models to Therapies.

Authors: Matías Montes; Brianne L Sanford; Daniel F Comiskey; Dawn S Chandler
Journal: Trends Genet Date: 2018-11-19 Impact factor: 11.639

4. A Comprehensive Map of Intron Branchpoints and Lariat RNAs in Plants.

Authors: Xiaotuo Zhang; Yong Zhang; Taiyun Wang; Ziwei Li; Jinping Cheng; Haoran Ge; Qi Tang; Kun Chen; Li Liu; Chenyu Lu; Junqiang Guo; Binglian Zheng; Yun Zheng
Journal: Plant Cell Date: 2019-03-20 Impact factor: 11.277

5. Pathogenic Abnormal Splicing Due to Intronic Deletions that Induce Biophysical Space Constraint for Spliceosome Assembly.

Authors: Samantha J Bryen; Himanshu Joshi; Frances J Evesson; Cyrille Girard; Roula Ghaoui; Leigh B Waddell; Alison C Testa; Beryl Cummings; Susan Arbuckle; Nicole Graf; Richard Webster; Daniel G MacArthur; Nigel G Laing; Mark R Davis; Reinhard Lührmann; Sandra T Cooper
Journal: Am J Hum Genet Date: 2019-08-22 Impact factor: 11.025

6. Genomic basis for RNA alterations in cancer.

Authors: Claudia Calabrese; Natalie R Davidson; Deniz Demircioğlu; Nuno A Fonseca; Yao He; André Kahles; Kjong-Van Lehmann; Fenglin Liu; Yuichi Shiraishi; Cameron M Soulette; Lara Urban; Liliana Greger; Siliang Li; Dongbing Liu; Marc D Perry; Qian Xiang; Fan Zhang; Junjun Zhang; Peter Bailey; Serap Erkek; Katherine A Hoadley; Yong Hou; Matthew R Huska; Helena Kilpinen; Jan O Korbel; Maximillian G Marin; Julia Markowski; Tannistha Nandi; Qiang Pan-Hammarström; Chandra Sekhar Pedamallu; Reiner Siebert; Stefan G Stark; Hong Su; Patrick Tan; Sebastian M Waszak; Christina Yung; Shida Zhu; Philip Awadalla; Chad J Creighton; Matthew Meyerson; B F Francis Ouellette; Kui Wu; Huanming Yang; Alvis Brazma; Angela N Brooks; Jonathan Göke; Gunnar Rätsch; Roland F Schwarz; Oliver Stegle; Zemin Zhang
Journal: Nature Date: 2020-02-05 Impact factor: 49.962