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Open Access 01-08-2009 | Research article

An integration of complementary strategies for gene-expression analysis to reveal novel therapeutic opportunities for breast cancer

Authors: Andrea H Bild, Joel S Parker, Adam M Gustafson, Chaitanya R Acharya, Katherine A Hoadley, Carey Anders, P Kelly Marcom, Lisa A Carey, Anil Potti, Joseph R Nevins, Charles M Perou

Published in: Breast Cancer Research | Issue 4/2009

Abstract

Introduction

Perhaps the major challenge in developing more effective therapeutic strategies for the treatment of breast cancer patients is confronting the heterogeneity of the disease, recognizing that breast cancer is not one disease but multiple disorders with distinct underlying mechanisms. Gene-expression profiling studies have been used to dissect this complexity, and our previous studies identified a series of intrinsic subtypes of breast cancer that define distinct populations of patients with respect to survival. Additional work has also used signatures of oncogenic pathway deregulation to dissect breast cancer heterogeneity as well as to suggest therapeutic opportunities linked to pathway activation.

Methods

We used genomic analyses to identify relations between breast cancer subtypes, pathway deregulation, and drug sensitivity. For these studies, we use three independent breast cancer gene-expression data sets to measure an individual tumor phenotype. Correlation between pathway status and subtype are examined and linked to predictions for response to conventional chemotherapies.

Results

We reveal patterns of pathway activation characteristic of each molecular breast cancer subtype, including within the more aggressive subtypes in which novel therapeutic opportunities are critically needed. Whereas some oncogenic pathways have high correlations to breast cancer subtype (RAS, CTNNB1, p53, HER1), others have high variability of activity within a specific subtype (MYC, E2F3, SRC), reflecting biology independent of common clinical factors. Additionally, we combined these analyses with predictions of sensitivity to commonly used cytotoxic chemotherapies to provide additional opportunities for therapeutics specific to the intrinsic subtype that might be better aligned with the characteristics of the individual patient.

Conclusions

Genomic analyses can be used to dissect the heterogeneity of breast cancer. We use an integrated analysis of breast cancer that combines independent methods of genomic analyses to highlight the complexity of signaling pathways underlying different breast cancer phenotypes and to identify optimal therapeutic opportunities.

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Title: An integration of complementary strategies for gene-expression analysis to reveal novel therapeutic opportunities for breast cancer
Authors: Andrea H Bild
Joel S Parker
Adam M Gustafson
Chaitanya R Acharya
Katherine A Hoadley
Carey Anders
P Kelly Marcom
Lisa A Carey
Anil Potti
Joseph R Nevins
Charles M Perou
Publication date: 01-08-2009
Publisher: BioMed Central
Published in: Breast Cancer Research / Issue 4/2009
Electronic ISSN: 1465-542X
DOI: https://doi.org/10.1186/bcr2344

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Abstract

Introduction

Methods

Results

Conclusions

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