Fan Zhu1, Lihong Shi1, Hongdong Li1, Ridvan Eksi1, James Douglas Engel1, Yuanfang Guan2. 1. Department of Computational Medicine and Bioinformatics, Department of Cell and Developmental Biology, Department of Internal Medicine and Department of Computer Science and Engineering, University of Michigan, MI48109, USA. 2. Department of Computational Medicine and Bioinformatics, Department of Cell and Developmental Biology, Department of Internal Medicine and Department of Computer Science and Engineering, University of Michigan, MI48109, USA Department of Computational Medicine and Bioinformatics, Department of Cell and Developmental Biology, Department of Internal Medicine and Department of Computer Science and Engineering, University of Michigan, MI48109, USA Department of Computational Medicine and Bioinformatics, Department of Cell and Developmental Biology, Department of Internal Medicine and Department of Computer Science and Engineering, University of Michigan, MI48109, USA.
Abstract
MOTIVATION: Functional relationship networks, which summarize the probability of co-functionality between any two genes in the genome, could complement the reductionist focus of modern biology for understanding diverse biological processes in an organism. One major limitation of the current networks is that they are static, while one might expect functional relationships to consistently reprogram during the differentiation of a cell lineage. To address this potential limitation, we developed a novel algorithm that leverages both differentiation stage-specific expression data and large-scale heterogeneous functional genomic data to model such dynamic changes. We then applied this algorithm to the time-course RNA-Seq data we collected for ex vivo human erythroid cell differentiation. RESULTS: Through computational cross-validation and literature validation, we show that the resulting networks correctly predict the (de)-activated functional connections between genes during erythropoiesis. We identified known critical genes, such as HBD and GATA1, and functional connections during erythropoiesis using these dynamic networks, while the traditional static network was not able to provide such information. Furthermore, by comparing the static and the dynamic networks, we identified novel genes (such as OSBP2 and PDZK1IP1) that are potential drivers of erythroid cell differentiation. This novel method of modeling dynamic networks is applicable to other differentiation processes where time-course genome-scale expression data are available, and should assist in generating greater understanding of the functional dynamics at play across the genome during development. AVAILABILITY AND IMPLEMENTATION: The network described in this article is available at http://guanlab.ccmb.med.umich.edu/stageSpecificNetwork.
MOTIVATION: Functional relationship networks, which summarize the probability of co-functionality between any two genes in the genome, could complement the reductionist focus of modern biology for understanding diverse biological processes in an organism. One major limitation of the current networks is that they are static, while one might expect functional relationships to consistently reprogram during the differentiation of a cell lineage. To address this potential limitation, we developed a novel algorithm that leverages both differentiation stage-specific expression data and large-scale heterogeneous functional genomic data to model such dynamic changes. We then applied this algorithm to the time-course RNA-Seq data we collected for ex vivo human erythroid cell differentiation. RESULTS: Through computational cross-validation and literature validation, we show that the resulting networks correctly predict the (de)-activated functional connections between genes during erythropoiesis. We identified known critical genes, such as HBD and GATA1, and functional connections during erythropoiesis using these dynamic networks, while the traditional static network was not able to provide such information. Furthermore, by comparing the static and the dynamic networks, we identified novel genes (such as OSBP2 and PDZK1IP1) that are potential drivers of erythroid cell differentiation. This novel method of modeling dynamic networks is applicable to other differentiation processes where time-course genome-scale expression data are available, and should assist in generating greater understanding of the functional dynamics at play across the genome during development. AVAILABILITY AND IMPLEMENTATION: The network described in this article is available at http://guanlab.ccmb.med.umich.edu/stageSpecificNetwork.
Authors: Lihong Shi; Yu-Hsuan Lin; M C Sierant; Fan Zhu; Shuaiying Cui; Yuanfang Guan; Maureen A Sartor; Osamu Tanabe; Kim-Chew Lim; James Douglas Engel Journal: Hum Mol Genet Date: 2014-04-29 Impact factor: 6.150
Authors: Yuanfang Guan; Dmitriy Gorenshteyn; Margit Burmeister; Aaron K Wong; John C Schimenti; Mary Ann Handel; Carol J Bult; Matthew A Hibbs; Olga G Troyanskaya Journal: PLoS Comput Biol Date: 2012-09-27 Impact factor: 4.475
Authors: Lourdes Peña-Castillo; Murat Tasan; Chad L Myers; Hyunju Lee; Trupti Joshi; Chao Zhang; Yuanfang Guan; Michele Leone; Andrea Pagnani; Wan Kyu Kim; Chase Krumpelman; Weidong Tian; Guillaume Obozinski; Yanjun Qi; Sara Mostafavi; Guan Ning Lin; Gabriel F Berriz; Francis D Gibbons; Gert Lanckriet; Jian Qiu; Charles Grant; Zafer Barutcuoglu; David P Hill; David Warde-Farley; Chris Grouios; Debajyoti Ray; Judith A Blake; Minghua Deng; Michael I Jordan; William S Noble; Quaid Morris; Judith Klein-Seetharaman; Ziv Bar-Joseph; Ting Chen; Fengzhu Sun; Olga G Troyanskaya; Edward M Marcotte; Dong Xu; Timothy R Hughes; Frederick P Roth Journal: Genome Biol Date: 2008-06-27 Impact factor: 13.583
Authors: Fan Zhu; Bharat Panwar; Hiroko H Dodge; Hongdong Li; Benjamin M Hampstead; Roger L Albin; Henry L Paulson; Yuanfang Guan Journal: Sci Rep Date: 2016-10-05 Impact factor: 4.379