Cellular network entropy as the energy potential in Waddington's differentiation landscape

Cellular network entropy as the energy potential in Waddington's differentiation landscape

Differentiation is a key cellular process in normal tissue development that is significantly altered in cancer. Although molecular signatures characterising pluripotency and multipotency exist, there is, as yet, no single quantitative mark of a cellular sample's position in the global different...

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Bibliographic Details
Published in:Scientific reports Vol. 3; no. 1; p. 3039
Main Authors: Banerji, Christopher R. S., Miranda-Saavedra, Diego, Severini, Simone, Widschwendter, Martin, Enver, Tariq, Zhou, Joseph X., Teschendorff, Andrew E.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 24-10-2013
Nature Publishing Group
Subjects:
631/114/2408
631/532/1360
631/553/1044
639/766/530/2801
Algorithms
Cancer
Cell Differentiation
Cell Lineage
Cell Physiological Phenomena
Entropy
Genomes
Heterogeneity
Humanities and Social Sciences
Humans
Models, Biological
multidisciplinary
Neoplasms - genetics
Neoplasms - metabolism
Pluripotency
Science
Signal Transduction
Stem cells
Stem Cells - physiology
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Summary:Differentiation is a key cellular process in normal tissue development that is significantly altered in cancer. Although molecular signatures characterising pluripotency and multipotency exist, there is, as yet, no single quantitative mark of a cellular sample's position in the global differentiation hierarchy. Here we adopt a systems view and consider the sample's network entropy, a measure of signaling pathway promiscuity, computable from a sample's genome-wide expression profile. We demonstrate that network entropy provides a quantitative, in-silico, readout of the average undifferentiated state of the profiled cells, recapitulating the known hierarchy of pluripotent, multipotent and differentiated cell types. Network entropy further exhibits dynamic changes in time course differentiation data, and in line with a sample's differentiation stage. In disease, network entropy predicts a higher level of cellular plasticity in cancer stem cell populations compared to ordinary cancer cells. Importantly, network entropy also allows identification of key differentiation pathways. Our results are consistent with the view that pluripotency is a statistical property defined at the cellular population level, correlating with intra-sample heterogeneity, and driven by the degree of signaling promiscuity in cells. In summary, network entropy provides a quantitative measure of a cell's undifferentiated state, defining its elevation in Waddington's landscape.
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ISSN:2045-2322
2045-2322
DOI:10.1038/srep03039