MOTIVATION: Gene set enrichment analysis has been shown to be effective in identifying relevant biological pathways underlying complex diseases. Existing approaches lack the ability to quantify the enrichment levels accurately, hence preventing the enrichment information to be further utilized in both upstream and downstream analyses. A modernized and rigorous approach for gene set enrichment analysis that emphasizes both hypothesis testing and enrichment estimation is much needed. RESULTS: We propose a novel computational method, Bayesian Analysis of Gene Set Enrichment (BAGSE), for gene set enrichment analysis. BAGSE is built on a Bayesian hierarchical model and fully accounts for the uncertainty embedded in the association evidence of individual genes. We adopt an empirical Bayes inference framework to fit the proposed hierarchical model by implementing an efficient EM algorithm. Through simulation studies, we illustrate that BAGSE yields accurate enrichment quantification while achieving similar power as the state-of-the-art methods. Further simulation studies show that BAGSE can effectively utilize the enrichment information to improve the power in gene discovery. Finally, we demonstrate the application of BAGSE in analyzing real data from a differential expression experiment and a transcriptome-wide association study. Our results indicate that the proposed statistical framework is effective in aiding the discovery of potentially causal pathways and gene networks. AVAILABILITY AND IMPLEMENTATION: BAGSE is implemented using the C++ programing language and is freely available from https://github.com/xqwen/bagse/. Simulated and real data used in this paper are also available at the Github repository for reproducibility purposes. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.
MOTIVATION: Gene set enrichment analysis has been shown to be effective in identifying relevant biological pathways underlying complex diseases. Existing approaches lack the ability to quantify the enrichment levels accurately, hence preventing the enrichment information to be further utilized in both upstream and downstream analyses. A modernized and rigorous approach for gene set enrichment analysis that emphasizes both hypothesis testing and enrichment estimation is much needed. RESULTS: We propose a novel computational method, Bayesian Analysis of Gene Set Enrichment (BAGSE), for gene set enrichment analysis. BAGSE is built on a Bayesian hierarchical model and fully accounts for the uncertainty embedded in the association evidence of individual genes. We adopt an empirical Bayes inference framework to fit the proposed hierarchical model by implementing an efficient EM algorithm. Through simulation studies, we illustrate that BAGSE yields accurate enrichment quantification while achieving similar power as the state-of-the-art methods. Further simulation studies show that BAGSE can effectively utilize the enrichment information to improve the power in gene discovery. Finally, we demonstrate the application of BAGSE in analyzing real data from a differential expression experiment and a transcriptome-wide association study. Our results indicate that the proposed statistical framework is effective in aiding the discovery of potentially causal pathways and gene networks. AVAILABILITY AND IMPLEMENTATION: BAGSE is implemented using the C++ programing language and is freely available from https://github.com/xqwen/bagse/. Simulated and real data used in this paper are also available at the Github repository for reproducibility purposes. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.
Authors: Zhihong Zhu; Futao Zhang; Han Hu; Andrew Bakshi; Matthew R Robinson; Joseph E Powell; Grant W Montgomery; Michael E Goddard; Naomi R Wray; Peter M Visscher; Jian Yang Journal: Nat Genet Date: 2016-03-28 Impact factor: 38.330
Authors: Ophir Shalem; Neville E Sanjana; Ella Hartenian; Xi Shi; David A Scott; Tarjei Mikkelson; Dirk Heckl; Benjamin L Ebert; David E Root; John G Doench; Feng Zhang Journal: Science Date: 2013-12-12 Impact factor: 47.728
Authors: Matthias Maruschke; Oliver W Hakenberg; Dirk Koczan; Wolfgang Zimmermann; Christian G Stief; Alexander Buchner Journal: Int J Urol Date: 2013-05-02 Impact factor: 3.369
Authors: Marko Elovainio; Tuukka Taipale; Ilkka Seppälä; Nina Mononen; Emma Raitoharju; Markus Jokela; Laura Pulkki-Råback; Thomas Illig; Melanie Waldenberger; Christian Hakulinen; Taina Hintsa; Mika Kivimäki; Mika Kähönen; Liisa Keltikangas-Järvinen; Olli Raitakari; Terho Lehtimäki Journal: J Psychiatr Res Date: 2015-10-22 Impact factor: 4.791
Authors: Jonas Richiardi; Andre Altmann; Anna-Clare Milazzo; Catie Chang; M Mallar Chakravarty; Tobias Banaschewski; Gareth J Barker; Arun L W Bokde; Uli Bromberg; Christian Büchel; Patricia Conrod; Mira Fauth-Bühler; Herta Flor; Vincent Frouin; Jürgen Gallinat; Hugh Garavan; Penny Gowland; Andreas Heinz; Hervé Lemaître; Karl F Mann; Jean-Luc Martinot; Frauke Nees; Tomáš Paus; Zdenka Pausova; Marcella Rietschel; Trevor W Robbins; Michael N Smolka; Rainer Spanagel; Andreas Ströhle; Gunter Schumann; Mike Hawrylycz; Jean-Baptiste Poline; Michael D Greicius Journal: Science Date: 2015-06-11 Impact factor: 47.728
Authors: Johanna Hass; Esther Walton; Carrie Wright; Andreas Beyer; Markus Scholz; Jessica Turner; Jingyu Liu; Michael N Smolka; Veit Roessner; Scott R Sponheim; Randy L Gollub; Vince D Calhoun; Stefan Ehrlich Journal: Prog Neuropsychopharmacol Biol Psychiatry Date: 2015-01-15 Impact factor: 5.067