| Item type: | Article | ||||
|---|---|---|---|---|---|
| Journal or Publication Title: | PLOS ONE | ||||
| Publisher: | PUBLIC LIBRARY SCIENCE | ||||
| Place of Publication: | SAN FRANCISCO | ||||
| Volume: | 10 | ||||
| Number of Issue or Book Chapter: | 12 | ||||
| Page Range: | e0144014 | ||||
| Date: | 2015 | ||||
| Institutions: | Medicine > Lehrstuhl für Innere Medizin III (Hämatologie und Internistische Onkologie) | ||||
| Identification Number: |
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| Keywords: | BETA-CATENIN; CELL-PROLIFERATION; WNT/BETA-CATENIN; MICROARRAY DATA; PATHWAY DATA; IDENTIFICATION; MIGRATION; MECHANISM; RESOURCE; SUBTYPES; | ||||
| Dewey Decimal Classification: | 600 Technology > 610 Medical sciences Medicine | ||||
| Status: | Published | ||||
| Refereed: | Yes, this version has been refereed | ||||
| Created at the University of Regensburg: | Yes | ||||
| Item ID: | 59857 |
Web of ScienceAbstract
Introduction WNT signaling is a complex process comprising multiple pathways: the canonical beta-catenin- dependent pathway and several alternative non-canonical pathways that act in a beta-catenin- independent manner. Representing these intricate signaling mechanisms through bioinformatic approaches is challenging. Nevertheless, a simplified but reliable bioinformatic WNT pathway model is ...
Abstract
Introduction WNT signaling is a complex process comprising multiple pathways: the canonical beta-catenin- dependent pathway and several alternative non-canonical pathways that act in a beta-catenin- independent manner. Representing these intricate signaling mechanisms through bioinformatic approaches is challenging. Nevertheless, a simplified but reliable bioinformatic WNT pathway model is needed, which can be further utilized to decipher specific WNT activation states within e.g. high-throughput data. Results In order to build such a model, we collected, parsed, and curated available WNT signaling knowledge from different pathway databases. The data were assembled to construct computationally suitable models of different WNT signaling cascades in the form of directed signaling graphs. This resulted in four networks representing canonical WNT signaling, non-canonical WNT signaling, the inhibition of canonical WNT signaling and the regulation of WNT signaling pathways, respectively. Furthermore, these networks were integrated with microarray and RNA sequencing data to gain deeper insight into the underlying biology of gene expression differences between MCF-7 and MDA-MB-231 breast cancer cell lines, representing weakly and highly invasive breast carcinomas, respectively. Differential genes up-regulated in the MDA-MB-231 compared to the MCF-7 cell line were found to display enrichment in the gene set originating from the non-canonical network. Moreover, we identified and validated differentially regulated modules representing canonical and non-canonical WNT pathway components specific for the aggressive basal-like breast cancer subtype. Conclusions In conclusion, we demonstrated that these newly constructed WNT networks reliably reflect distinct WNT signaling processes. Using transcriptomic data, we shaped these networks into comprehensive modules of the genes implicated in the aggressive basal-like breast cancer subtype and demonstrated that non-canonical WNT signaling is important in this context. The topology of these networks can be further refined in the future by integration with complementary data such as protein-protein interactions, in order to gain greater insight into signaling processes.
Metadata last modified: 19 Dec 2024 07:19
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