Literature DB >> 34469537

Evidence in disease and non-disease contexts that nonsense mutations cause altered splicing via motif disruption.

Liam Abrahams1, Rosina Savisaar1,2, Christine Mordstein1,3,4, Bethan Young3, Grzegorz Kudla3, Laurence D Hurst1.   

Abstract

Transcripts containing premature termination codons (PTCs) can be subject to nonsense-associated alternative splicing (NAS). Two models have been evoked to explain this, scanning and splice motif disruption. The latter postulates that exonic cis motifs, such as exonic splice enhancers (ESEs), are disrupted by nonsense mutations. We employ genome-wide transcriptomic and k-mer enrichment methods to scrutinize this model. First, we show that ESEs are prone to disruptive nonsense mutations owing to their purine richness and paucity of TGA, TAA and TAG. The motif model correctly predicts that NAS rates should be low (we estimate 5-30%) and approximately in line with estimates for the rate at which random point mutations disrupt splicing (8-20%). Further, we find that, as expected, NAS-associated PTCs are predictable from nucleotide-based machine learning approaches to predict splice disruption and, at least for pathogenic variants, are enriched in ESEs. Finally, we find that both in and out of frame mutations to TAA, TGA or TAG are associated with exon skipping. While a higher relative frequency of such skip-inducing mutations in-frame than out of frame lends some credence to the scanning model, these results reinforce the importance of considering splice motif modulation to understand the etiology of PTC-associated disease.
© The Author(s) 2021. Published by Oxford University Press on behalf of Nucleic Acids Research.

Entities:  

Mesh:

Substances:

Year:  2021        PMID: 34469537      PMCID: PMC8464065          DOI: 10.1093/nar/gkab750

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


  137 in total

1.  Synonymous SNPs provide evidence for selective constraint on human exonic splicing enhancers.

Authors:  David B Carlini; Jordan E Genut
Journal:  J Mol Evol       Date:  2005-11-30       Impact factor: 2.395

2.  Linking C5 deficiency to an exonic splicing enhancer mutation.

Authors:  Nicole Pfarr; Dirk Prawitt; Michael Kirschfink; Claudia Schroff; Markus Knuf; Pirmin Habermehl; Wilma Mannhardt; Fred Zepp; William G Fairbrother; William Fairbrother; Michael Loos; Christopher B Burge; Joachim Pohlenz
Journal:  J Immunol       Date:  2005-04-01       Impact factor: 5.422

3.  Using positional distribution to identify splicing elements and predict pre-mRNA processing defects in human genes.

Authors:  Kian Huat Lim; Luciana Ferraris; Madeleine E Filloux; Benjamin J Raphael; William G Fairbrother
Journal:  Proc Natl Acad Sci U S A       Date:  2011-06-17       Impact factor: 11.205

4.  Genomic features defining exonic variants that modulate splicing.

Authors:  Adam Woolfe; James C Mullikin; Laura Elnitski
Journal:  Genome Biol       Date:  2010-02-16       Impact factor: 13.583

5.  A promoter-level mammalian expression atlas.

Authors:  Alistair R R Forrest; Hideya Kawaji; Michael Rehli; J Kenneth Baillie; Michiel J L de Hoon; Vanja Haberle; Timo Lassmann; Ivan V Kulakovskiy; Marina Lizio; Masayoshi Itoh; Robin Andersson; Christopher J Mungall; Terrence F Meehan; Sebastian Schmeier; Nicolas Bertin; Mette Jørgensen; Emmanuel Dimont; Erik Arner; Christian Schmidl; Ulf Schaefer; Yulia A Medvedeva; Charles Plessy; Morana Vitezic; Jessica Severin; Colin A Semple; Yuri Ishizu; Robert S Young; Margherita Francescatto; Intikhab Alam; Davide Albanese; Gabriel M Altschuler; Takahiro Arakawa; John A C Archer; Peter Arner; Magda Babina; Sarah Rennie; Piotr J Balwierz; Anthony G Beckhouse; Swati Pradhan-Bhatt; Judith A Blake; Antje Blumenthal; Beatrice Bodega; Alessandro Bonetti; James Briggs; Frank Brombacher; A Maxwell Burroughs; Andrea Califano; Carlo V Cannistraci; Daniel Carbajo; Yun Chen; Marco Chierici; Yari Ciani; Hans C Clevers; Emiliano Dalla; Carrie A Davis; Michael Detmar; Alexander D Diehl; Taeko Dohi; Finn Drabløs; Albert S B Edge; Matthias Edinger; Karl Ekwall; Mitsuhiro Endoh; Hideki Enomoto; Michela Fagiolini; Lynsey Fairbairn; Hai Fang; Mary C Farach-Carson; Geoffrey J Faulkner; Alexander V Favorov; Malcolm E Fisher; Martin C Frith; Rie Fujita; Shiro Fukuda; Cesare Furlanello; Masaaki Furino; Jun-ichi Furusawa; Teunis B Geijtenbeek; Andrew P Gibson; Thomas Gingeras; Daniel Goldowitz; Julian Gough; Sven Guhl; Reto Guler; Stefano Gustincich; Thomas J Ha; Masahide Hamaguchi; Mitsuko Hara; Matthias Harbers; Jayson Harshbarger; Akira Hasegawa; Yuki Hasegawa; Takehiro Hashimoto; Meenhard Herlyn; Kelly J Hitchens; Shannan J Ho Sui; Oliver M Hofmann; Ilka Hoof; Furni Hori; Lukasz Huminiecki; Kei Iida; Tomokatsu Ikawa; Boris R Jankovic; Hui Jia; Anagha Joshi; Giuseppe Jurman; Bogumil Kaczkowski; Chieko Kai; Kaoru Kaida; Ai Kaiho; Kazuhiro Kajiyama; Mutsumi Kanamori-Katayama; Artem S Kasianov; Takeya Kasukawa; Shintaro Katayama; Sachi Kato; Shuji Kawaguchi; Hiroshi Kawamoto; Yuki I Kawamura; Tsugumi Kawashima; Judith S Kempfle; Tony J Kenna; Juha Kere; Levon M Khachigian; Toshio Kitamura; S Peter Klinken; Alan J Knox; Miki Kojima; Soichi Kojima; Naoto Kondo; Haruhiko Koseki; Shigeo Koyasu; Sarah Krampitz; Atsutaka Kubosaki; Andrew T Kwon; Jeroen F J Laros; Weonju Lee; Andreas Lennartsson; Kang Li; Berit Lilje; Leonard Lipovich; Alan Mackay-Sim; Ri-ichiroh Manabe; Jessica C Mar; Benoit Marchand; Anthony Mathelier; Niklas Mejhert; Alison Meynert; Yosuke Mizuno; David A de Lima Morais; Hiromasa Morikawa; Mitsuru Morimoto; Kazuyo Moro; Efthymios Motakis; Hozumi Motohashi; Christine L Mummery; Mitsuyoshi Murata; Sayaka Nagao-Sato; Yutaka Nakachi; Fumio Nakahara; Toshiyuki Nakamura; Yukio Nakamura; Kenichi Nakazato; Erik van Nimwegen; Noriko Ninomiya; Hiromi Nishiyori; Shohei Noma; Shohei Noma; Tadasuke Noazaki; Soichi Ogishima; Naganari Ohkura; Hiroko Ohimiya; Hiroshi Ohno; Mitsuhiro Ohshima; Mariko Okada-Hatakeyama; Yasushi Okazaki; Valerio Orlando; Dmitry A Ovchinnikov; Arnab Pain; Robert Passier; Margaret Patrikakis; Helena Persson; Silvano Piazza; James G D Prendergast; Owen J L Rackham; Jordan A Ramilowski; Mamoon Rashid; Timothy Ravasi; Patrizia Rizzu; Marco Roncador; Sugata Roy; Morten B Rye; Eri Saijyo; Antti Sajantila; Akiko Saka; Shimon Sakaguchi; Mizuho Sakai; Hiroki Sato; Suzana Savvi; Alka Saxena; Claudio Schneider; Erik A Schultes; Gundula G Schulze-Tanzil; Anita Schwegmann; Thierry Sengstag; Guojun Sheng; Hisashi Shimoji; Yishai Shimoni; Jay W Shin; Christophe Simon; Daisuke Sugiyama; Takaai Sugiyama; Masanori Suzuki; Naoko Suzuki; Rolf K Swoboda; Peter A C 't Hoen; Michihira Tagami; Naoko Takahashi; Jun Takai; Hiroshi Tanaka; Hideki Tatsukawa; Zuotian Tatum; Mark Thompson; Hiroo Toyodo; Tetsuro Toyoda; Elvind Valen; Marc van de Wetering; Linda M van den Berg; Roberto Verado; Dipti Vijayan; Ilya E Vorontsov; Wyeth W Wasserman; Shoko Watanabe; Christine A Wells; Louise N Winteringham; Ernst Wolvetang; Emily J Wood; Yoko Yamaguchi; Masayuki Yamamoto; Misako Yoneda; Yohei Yonekura; Shigehiro Yoshida; Susan E Zabierowski; Peter G Zhang; Xiaobei Zhao; Silvia Zucchelli; Kim M Summers; Harukazu Suzuki; Carsten O Daub; Jun Kawai; Peter Heutink; Winston Hide; Tom C Freeman; Boris Lenhard; Vladimir B Bajic; Martin S Taylor; Vsevolod J Makeev; Albin Sandelin; David A Hume; Piero Carninci; Yoshihide Hayashizaki
Journal:  Nature       Date:  2014-03-27       Impact factor: 49.962

6.  Visualization of the joining of ribosomal subunits reveals the presence of 80S ribosomes in the nucleus.

Authors:  Khalid Al-Jubran; Jikai Wen; Akilu Abdullahi; Subhendu Roy Chaudhury; Min Li; Preethi Ramanathan; Annunziata Matina; Sandip De; Kim Piechocki; Kushal Nivriti Rugjee; Saverio Brogna
Journal:  RNA       Date:  2013-10-15       Impact factor: 4.942

7.  A Depletion of Stop Codons in lincRNA is Owing to Transfer of Selective Constraint from Coding Sequences.

Authors:  Liam Abrahams; Laurence D Hurst
Journal:  Mol Biol Evol       Date:  2020-04-01       Impact factor: 16.240

8.  Single nucleotide polymorphism-based validation of exonic splicing enhancers.

Authors:  William G Fairbrother; Dirk Holste; Christopher B Burge; Phillip A Sharp
Journal:  PLoS Biol       Date:  2004-08-31       Impact factor: 8.029

9.  Germline mutation in the RAD51B gene confers predisposition to breast cancer.

Authors:  Lisa Golmard; Virginie Caux-Moncoutier; Grégoire Davy; Essam Al Ageeli; Brigitte Poirot; Carole Tirapo; Dorothée Michaux; Catherine Barbaroux; Catherine Dubois d'Enghien; André Nicolas; Laurent Castéra; Xavier Sastre-Garau; Marc-Henri Stern; Claude Houdayer; Dominique Stoppa-Lyonnet
Journal:  BMC Cancer       Date:  2013-10-19       Impact factor: 4.430

Review 10.  Progress and promise in understanding the genetic basis of common diseases.

Authors:  Alkes L Price; Chris C A Spencer; Peter Donnelly
Journal:  Proc Biol Sci       Date:  2015-12-22       Impact factor: 5.349
View more
  3 in total

1.  In rice splice variants that restore the reading frame after frameshifting indel introduction are common, often induced by the indels and sometimes lead to organism-level rescue.

Authors:  Yanxiao Jia; Chao Qin; Milton Brian Traw; Xiaonan Chen; Ying He; Jing Kai; Sihai Yang; Long Wang; Laurence D Hurst
Journal:  PLoS Genet       Date:  2022-02-18       Impact factor: 5.917

2.  T-G-A Deficiency Pattern in Protein-Coding Genes and Its Potential Reason.

Authors:  Yan-Ting Jin; Dong-Kai Pu; Hai-Xia Guo; Zixin Deng; Ling-Ling Chen; Feng-Biao Guo
Journal:  Front Microbiol       Date:  2022-05-04       Impact factor: 5.640

3.  Twelve exonic variants in the SLC12A1 and CLCNKB genes alter RNA splicing in a minigene assay.

Authors:  Qing Xin; Qihua Liu; Zhiying Liu; Xiaomeng Shi; Xuyan Liu; Ruixiao Zhang; Yefeng Hong; Xiangzhong Zhao; Leping Shao
Journal:  Front Genet       Date:  2022-08-25       Impact factor: 4.772
  3 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.