Open AccessModeling dynamic functional relationship networks and application to ex vivo human erythroid differentiation
Author(s) -
Fan Zhu,
Lihong Shi,
HongDong Li,
Ridvan Eksi,
James Douglas Engel,
Yuanfang Guan
Publication year - 2014
Publication title -
bioinformatics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.599
H-Index - 390
eISSN - 1367-4811
pISSN - 1367-4803
DOI - 10.1093/bioinformatics/btu542
Subject(s) - computational biology , gene regulatory network , systems biology , complement (music) , computer science , biology , cellular differentiation , genome , erythropoiesis , functional genomics , gene , phenotype , genetics , gene expression , genomics , complementation , medicine , anemia
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.
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