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Reverse enGENEering of regulatory networks from Big Data: a guide for a biologist

Omics technologies enable unbiased investigation of biological systems through massively parallel sequence acquisition or molecular measurements, bringing the life sciences into the era of Big Data. A central challenge posed by such omics datasets is how to transform this data into biological knowledge. For example, how to use this data to answer questions such as: which functional pathways are involved in cell differentiation? Which genes should we target to stop cancer? Network analysis is a powerful and general approach to solve this problem consisting of two fundamental stages, network reconstruction and network interrogation. Herein, we provide an overview of network analysis including a step by step guide on how to perform and use this approach to investigate a biological question. In this guide, we also include the software packages that we and others employ for each of the steps of a network analysis workflow.

preprint2014arXivOpen access
Xiaoxi DongAnatoly YambartsevStephen RamseyLina ThomasNatalia ShulzhenkoAndrey Morgun
Molecular Networks
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Open access6 authors1 topic
Imported metadata coverageMissing code, dataset, citation and institution fields are tracked without dominating the paper.Details
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Xiaoxi DongAnatoly YambartsevStephen RamseyLina ThomasNatalia ShulzhenkoAndrey Morgun

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