MOTIVATION: Alternative splicing is a major contributor to cellular diversity in mammalian tissues and relates to many human diseases. An important goal in understanding this phenomenon is to infer a 'splicing code' that predicts how splicing is regulated in different cell types by features derived from RNA, DNA and epigenetic modifiers. METHODS: We formulate the assembly of a splicing code as a problem of statistical inference and introduce a Bayesian method that uses an adaptively selected number of hidden variables to combine subgroups of features into a network, allows different tissues to share feature subgroups and uses a Gibbs sampler to hedge predictions and ascertain the statistical significance of identified features. RESULTS: Using data for 3665 cassette exons, 1014 RNA features and 4 tissue types derived from 27 mouse tissues (http://genes.toronto.edu/wasp), we benchmarked several methods. Our method outperforms all others, and achieves relative improvements of 52% in splicing code quality and up to 22% in classification error, compared with the state of the art. Novel combinations of regulatory features and novel combinations of tissues that share feature subgroups were identified using our method. CONTACT: frey@psi.toronto.edu SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.
MOTIVATION: Alternative splicing is a major contributor to cellular diversity in mammalian tissues and relates to many human diseases. An important goal in understanding this phenomenon is to infer a 'splicing code' that predicts how splicing is regulated in different cell types by features derived from RNA, DNA and epigenetic modifiers. METHODS: We formulate the assembly of a splicing code as a problem of statistical inference and introduce a Bayesian method that uses an adaptively selected number of hidden variables to combine subgroups of features into a network, allows different tissues to share feature subgroups and uses a Gibbs sampler to hedge predictions and ascertain the statistical significance of identified features. RESULTS: Using data for 3665 cassette exons, 1014 RNA features and 4 tissue types derived from 27 mouse tissues (http://genes.toronto.edu/wasp), we benchmarked several methods. Our method outperforms all others, and achieves relative improvements of 52% in splicing code quality and up to 22% in classification error, compared with the state of the art. Novel combinations of regulatory features and novel combinations of tissues that share feature subgroups were identified using our method. CONTACT: frey@psi.toronto.edu SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.
Authors: Hong Han; Manuel Irimia; P Joel Ross; Hoon-Ki Sung; Babak Alipanahi; Laurent David; Azadeh Golipour; Mathieu Gabut; Iacovos P Michael; Emil N Nachman; Eric Wang; Dan Trcka; Tadeo Thompson; Dave O'Hanlon; Valentina Slobodeniuc; Nuno L Barbosa-Morais; Christopher B Burge; Jason Moffat; Brendan J Frey; Andras Nagy; James Ellis; Jeffrey L Wrana; Benjamin J Blencowe Journal: Nature Date: 2013-06-05 Impact factor: 49.962
Authors: Hui Y Xiong; Babak Alipanahi; Leo J Lee; Hannes Bretschneider; Daniele Merico; Ryan K C Yuen; Yimin Hua; Serge Gueroussov; Hamed S Najafabadi; Timothy R Hughes; Quaid Morris; Yoseph Barash; Adrian R Krainer; Nebojsa Jojic; Stephen W Scherer; Benjamin J Blencowe; Brendan J Frey Journal: Science Date: 2014-12-18 Impact factor: 47.728
Authors: Travers Ching; Daniel S Himmelstein; Brett K Beaulieu-Jones; Alexandr A Kalinin; Brian T Do; Gregory P Way; Enrico Ferrero; Paul-Michael Agapow; Michael Zietz; Michael M Hoffman; Wei Xie; Gail L Rosen; Benjamin J Lengerich; Johnny Israeli; Jack Lanchantin; Stephen Woloszynek; Anne E Carpenter; Avanti Shrikumar; Jinbo Xu; Evan M Cofer; Christopher A Lavender; Srinivas C Turaga; Amr M Alexandari; Zhiyong Lu; David J Harris; Dave DeCaprio; Yanjun Qi; Anshul Kundaje; Yifan Peng; Laura K Wiley; Marwin H S Segler; Simina M Boca; S Joshua Swamidass; Austin Huang; Anthony Gitter; Casey S Greene Journal: J R Soc Interface Date: 2018-04 Impact factor: 4.293