A New Approach for Identification of Cancer-related Pathways using Protein Networks and Genomic Data

A New Approach for Identification of Cancer-related Pathways using Protein Networks and Genomic Data

Cancer cells have anomalous development and proliferation due to disturbances in their control systems. The study of the behavior of cellular control system requires high-throughput dynamical data. Unfortunately, this type of data is not largely available. This fact motivates the main issue of this...

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Bibliographic Details
Published in:Cancer informatics Vol. 2015; no. Suppl. 5; pp. 139 - 149
Main Authors: Fonseca, André, Gubitoso, Marco D., Reis, Marcelo S., De Souza, Sandro J., Barrera, Junior
Format: Journal Article
Language:English
Published: London, England SAGE Publishing 01-01-2015
SAGE Publications
Subjects:
Cancer
Cellular
Control systems
Gain
Genes
Networks
Pathways
Proteins
pathway
cancer
motifs
omic data
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Summary:Cancer cells have anomalous development and proliferation due to disturbances in their control systems. The study of the behavior of cellular control system requires high-throughput dynamical data. Unfortunately, this type of data is not largely available. This fact motivates the main issue of this article: how to use static omics data and available biological knowledge to get new information about the elements of the control system in cancer cells. Two important measures to access the state of the cellular control system are the gene expression profile and the signaling pathways. This article uses a combination of these two static omics data to gain insights on the states of a cancer cell. To extract information from this kind of data, a statistical computational model was formalized and implemented. In order to exemplify the application of some aspects of the developed conceptual framework, we verified the hypothesis that different types of cancer cells have different disturbed signaling pathways. To this end, we developed a method that recovers small protein networks, called motifs, which are differentially represented in some subtypes of breast cancer. These differentially represented motifs are enriched with specific gene ontologies as well as with new putative cancer genes.
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ISSN:1176-9351
1176-9351
DOI:10.4137/CIN.S30800