MicroRNA-based regulation of epithelial–hybrid–mesenchymal fate determination

Forward and backward transitions between epithelial and mesenchymal phenotypes play crucial roles in embryonic development and tissue repair. Aberrantly regulated transitions are also a hallmark of cancer metastasis. The genetic network that regulates these transitions appears to allow for the exist...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2013-11, Vol.110 (45), p.18144-18149
Main Authors: Lu, Mingyang, Jolly, Mohit Kumar, Levine, Herbert, Onuchic, José N., Ben-Jacob, Eshel
Format: Article
Language:English
Subjects:
Biological Sciences
Carcinogenesis - metabolism
Cell adhesion & migration
Cell Line
Cell lines
Cell Movement - physiology
Control loops
Epithelial cells
Epithelial-Mesenchymal Transition - physiology
Feedback circuits
Gene expression
Gene Expression Regulation - physiology
Genotype & phenotype
Homeodomain Proteins - metabolism
Humans
Hybridity
Mesenchymal stem cells
Messenger RNA
Metastasis
MicroRNA
MicroRNAs - metabolism
Models, Biological
Phenotypes
Snail Family Transcription Factors
Snails
Stem cells
Transcription Factors - metabolism
Zinc Finger E-box-Binding Homeobox 1
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Summary:Forward and backward transitions between epithelial and mesenchymal phenotypes play crucial roles in embryonic development and tissue repair. Aberrantly regulated transitions are also a hallmark of cancer metastasis. The genetic network that regulates these transitions appears to allow for the existence of a hybrid phenotype (epithelial/mesenchymal). Hybrid cells are endowed with mixed epithelial and mesenchymal characteristics, enabling specialized capabilities such as collective cell migration. Cell-fate determination between the three phenotypes is in fact regulated by a circuit composed of two highly interconnected chimeric modules—the miR-34/SNAIL and the miR-200/ZEB mutual-inhibition feedback circuits. Here, we used detailed modeling of microRNA-based regulation to study this core unit. More specifically, we investigated the functions of the two isolated modules and subsequently of the combined unit when the two modules are integrated into the full regulatory circuit. We found that miR-200/ZEB forms a tristable circuit that acts as a ternary switch, driven by miR-34/SNAIL, that is a monostable module that acts as a noise-buffering integrator of internal and external signals. We propose to associate the three stable states—(1,0), (high miR-200)/(low ZEB); (0,1), (low miR-200)/(high ZEB); and (1/2,1/2), (medium miR-200)/(medium ZEB)—with the epithelial, mesenchymal, and hybrid phenotypes, respectively. Our (1/2,1/2) state hypothesis is consistent with recent experimental studies (e.g., ZEB expression measurements in collectively migrating cells) and explains the lack of observed mesenchymal-to-hybrid transitions in metastatic cells and in induced pluripotent stem cells. Testable predictions of dynamic gene expression during complete and partial transitions are presented.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1318192110