Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Integrative transcriptome sequencing reveals extensive alternative trans-splicing and cis-backsplicing in human cells.

Literature DB >> 29385530

Integrative transcriptome sequencing reveals extensive alternative trans-splicing and cis-backsplicing in human cells.

Trees-Juen Chuang^1,2, Yen-Ju Chen^1,2, Chia-Ying Chen¹, Te-Lun Mai¹, Yi-Da Wang¹, Chung-Shu Yeh^1,3, Min-Yu Yang¹, Yu-Ting Hsiao¹, Tien-Hsien Chang¹, Tzu-Chien Kuo¹, Hsin-Hua Cho¹, Chia-Ning Shen¹, Hung-Chih Kuo⁴, Mei-Yeh Lu⁵, Yi-Hua Chen⁵, Shan-Chi Hsieh⁴, Tai-Wei Chiang¹.

Abstract

Transcriptionally non-co-linear (NCL) transcripts can originate from trans-splicing (trans-spliced RNA; 'tsRNA') or cis-backsplicing (circular RNA; 'circRNA'). While numerous circRNAs have been detected in various species, tsRNAs remain largely uninvestigated. Here, we utilize integrative transcriptome sequencing of poly(A)- and non-poly(A)-selected RNA-seq data from diverse human cell lines to distinguish between tsRNAs and circRNAs. We identified 24,498 NCL events and found that a considerable proportion (20-35%) of them arise from both tsRNAs and circRNAs, representing extensive alternative trans-splicing and cis-backsplicing in human cells. We show that sequence generalities of exon circularization are also observed in tsRNAs. Recapitulation of NCL RNAs further shows that inverted Alu repeats can simultaneously promote the formation of tsRNAs and circRNAs. However, tsRNAs and circRNAs exhibit quite different, or even opposite, expression patterns, in terms of correlation with the expression of their co-linear counterparts, expression breadth/abundance, transcript stability, and subcellular localization preference. These results indicate that tsRNAs and circRNAs may play different regulatory roles and analysis of NCL events should take the joint effects of different NCL-splicing types and joint effects of multiple NCL events into consideration. This study describes the first transcriptome-wide analysis of trans-splicing and cis-backsplicing, expanding our understanding of the complexity of the human transcriptome.

Entities: CellLine Chemical Disease Gene Mutation Species

Mesh：

Substances：
RNA, Circular
RNA

Year: 2018 PMID： 29385530 PMCID： PMC6283421 DOI： 10.1093/nar/gky032

Source DB: PubMed Journal: Nucleic Acids Res ISSN： 0305-1048 Impact factor: 16.971

88 in total

1. Global analysis of trans-splicing in Drosophila.

Authors: C Joel McManus; Michael O Duff; Jodi Eipper-Mains; Brenton R Graveley
Journal: Proc Natl Acad Sci U S A Date: 2010-07-01 Impact factor: 11.205

2. Understanding relationship between sequence and functional evolution in yeast proteins.

Authors: Seong-Ho Kim; Soojin V Yi
Journal: Genetica Date: 2006-12-12 Impact factor: 1.082

3. Scrambled exons.

Authors: J M Nigro; K R Cho; E R Fearon; S E Kern; J M Ruppert; J D Oliner; K W Kinzler; B Vogelstein
Journal: Cell Date: 1991-02-08 Impact factor: 41.582

4. Detecting and characterizing circular RNAs.

Authors: William R Jeck; Norman E Sharpless
Journal: Nat Biotechnol Date: 2014-05 Impact factor: 54.908

5. Circular intronic long noncoding RNAs.

Authors: Yang Zhang; Xiao-Ou Zhang; Tian Chen; Jian-Feng Xiang; Qing-Fei Yin; Yu-Hang Xing; Shanshan Zhu; Li Yang; Ling-Ling Chen
Journal: Mol Cell Date: 2013-09-12 Impact factor: 17.970

6. A high-resolution map of human evolutionary constraint using 29 mammals.

Authors: Kerstin Lindblad-Toh; Manuel Garber; Or Zuk; Michael F Lin; Brian J Parker; Stefan Washietl; Pouya Kheradpour; Jason Ernst; Gregory Jordan; Evan Mauceli; Lucas D Ward; Craig B Lowe; Alisha K Holloway; Michele Clamp; Sante Gnerre; Jessica Alföldi; Kathryn Beal; Jean Chang; Hiram Clawson; James Cuff; Federica Di Palma; Stephen Fitzgerald; Paul Flicek; Mitchell Guttman; Melissa J Hubisz; David B Jaffe; Irwin Jungreis; W James Kent; Dennis Kostka; Marcia Lara; Andre L Martins; Tim Massingham; Ida Moltke; Brian J Raney; Matthew D Rasmussen; Jim Robinson; Alexander Stark; Albert J Vilella; Jiayu Wen; Xiaohui Xie; Michael C Zody; Jen Baldwin; Toby Bloom; Chee Whye Chin; Dave Heiman; Robert Nicol; Chad Nusbaum; Sarah Young; Jane Wilkinson; Kim C Worley; Christie L Kovar; Donna M Muzny; Richard A Gibbs; Andrew Cree; Huyen H Dihn; Gerald Fowler; Shalili Jhangiani; Vandita Joshi; Sandra Lee; Lora R Lewis; Lynne V Nazareth; Geoffrey Okwuonu; Jireh Santibanez; Wesley C Warren; Elaine R Mardis; George M Weinstock; Richard K Wilson; Kim Delehaunty; David Dooling; Catrina Fronik; Lucinda Fulton; Bob Fulton; Tina Graves; Patrick Minx; Erica Sodergren; Ewan Birney; Elliott H Margulies; Javier Herrero; Eric D Green; David Haussler; Adam Siepel; Nick Goldman; Katherine S Pollard; Jakob S Pedersen; Eric S Lander; Manolis Kellis
Journal: Nature Date: 2011-10-12 Impact factor: 49.962

7. TTBK2 circular RNA promotes glioma malignancy by regulating miR-217/HNF1β/Derlin-1 pathway.

Authors: Jian Zheng; Xiaobai Liu; Yixue Xue; Wei Gong; Jun Ma; Zhuo Xi; Zhongyou Que; Yunhui Liu
Journal: J Hematol Oncol Date: 2017-02-20 Impact factor: 17.388

8. ChimerDB 2.0--a knowledgebase for fusion genes updated.

Authors: Pora Kim; Suhyeon Yoon; Namshin Kim; Sanghyun Lee; Minjeong Ko; Haeseung Lee; Hyunjung Kang; Jaesang Kim; Sanghyuk Lee
Journal: Nucleic Acids Res Date: 2009-11-11 Impact factor: 16.971

9. Circular RNAs are long-lived and display only minimal early alterations in response to a growth factor.

Authors: Yehoshua Enuka; Mattia Lauriola; Morris E Feldman; Aldema Sas-Chen; Igor Ulitsky; Yosef Yarden
Journal: Nucleic Acids Res Date: 2015-12-10 Impact factor: 16.971

10. Combinatorial control of Drosophila circular RNA expression by intronic repeats, hnRNPs, and SR proteins.

Authors: Marianne C Kramer; Dongming Liang; Deirdre C Tatomer; Beth Gold; Zachary M March; Sara Cherry; Jeremy E Wilusz
Journal: Genes Dev Date: 2015-10-08 Impact factor: 11.361

23 in total

1. Circular RNA-encoded oncogenic E-cadherin variant promotes glioblastoma tumorigenicity through activation of EGFR-STAT3 signalling.

Authors: Xinya Gao; Xin Xia; Fanying Li; Maolei Zhang; Huangkai Zhou; Xujia Wu; Jian Zhong; Zheng Zhao; Kun Zhao; Dawei Liu; Feizhe Xiao; Qiang Xu; Tao Jiang; Bo Li; Shi-Yuan Cheng; Nu Zhang
Journal: Nat Cell Biol Date: 2021-03-04 Impact factor: 28.824

2. Evidence of constraint in the 3D genome for trans-splicing in human cells.

Authors: Cong Liu; Yiqun Zhang; Xiaoli Li; Yan Jia; Feifei Li; Jing Li; Zhihua Zhang
Journal: Sci China Life Sci Date: 2020-03-26 Impact factor: 6.038

Review 3. The expanding regulatory mechanisms and cellular functions of circular RNAs.

Authors: Ling-Ling Chen
Journal: Nat Rev Mol Cell Biol Date: 2020-05-04 Impact factor: 94.444

Review 4. How RNA structure dictates the usage of a critical exon of spinal muscular atrophy gene.

Authors: Natalia N Singh; Ravindra N Singh
Journal: Biochim Biophys Acta Gene Regul Mech Date: 2019-07-16 Impact factor: 4.490

5. Trans-genetic effects of circular RNA expression quantitative trait loci and potential causal mechanisms in autism.

Authors: Te-Lun Mai; Chia-Ying Chen; Yu-Chen Chen; Tai-Wei Chiang; Trees-Juen Chuang
Journal: Mol Psychiatry Date: 2022-08-12 Impact factor: 13.437

Review 6. Best practice standards for circular RNA research.

Authors: Anne F Nielsen; Albrecht Bindereif; Irene Bozzoni; Mor Hanan; Thomas B Hansen; Manuel Irimia; Sebastian Kadener; Lasse S Kristensen; Ivano Legnini; Mariangela Morlando; Morten T Jarlstad Olesen; R Jeroen Pasterkamp; Stephan Preibisch; Nikolaus Rajewsky; Christin Suenkel; Jørgen Kjems
Journal: Nat Methods Date: 2022-05-26 Impact factor: 47.990