Enhancer Transcription Reveals Subtype-specific Gene Expression Programs Controlling Breast Cancer Pathogenesis

Overview

Journal Genome Res

Specialty Genetics

Date 2017 Dec 24

PMID 29273624

Citations 87

Authors

Hector L Franco

Anusha Nagari

Venkat S Malladi

Wenqian Li

Yuanxin Xi

Dana Richardson

Kendra L Allton

Kaori Tanaka

Jing Li

Shino Murakami

Khandan Keyomarsi

Mark T Bedford

Xiaobing Shi

Wei Li

Michelle C Barton

Sharon Y R Dent

W Lee Kraus

Affiliations

Soon will be listed here.

Abstract

Noncoding transcription is a defining feature of active enhancers, linking transcription factor (TF) binding to the molecular mechanisms controlling gene expression. To determine the relationship between enhancer activity and biological outcomes in breast cancers, we profiled the transcriptomes (using GRO-seq and RNA-seq) and epigenomes (using ChIP-seq) of 11 different human breast cancer cell lines representing five major molecular subtypes of breast cancer, as well as two immortalized ("normal") human breast cell lines. In addition, we developed a robust and unbiased computational pipeline that simultaneously identifies putative subtype-specific enhancers and their cognate TFs by integrating the magnitude of enhancer transcription, TF mRNA expression levels, TF motif -values, and enrichment of H3K4me1 and H3K27ac. When applied across the 13 different cell lines noted above, the Total Functional Score of Enhancer Elements (TFSEE) identified key breast cancer subtype-specific TFs that act at transcribed enhancers to dictate gene expression patterns determining growth outcomes, including Forkhead TFs, FOSL1, and PLAG1. FOSL1, a Fos family TF, (1) is highly enriched at the enhancers of triple negative breast cancer (TNBC) cells, (2) acts as a key regulator of the proliferation and viability of TNBC cells, but not Luminal A cells, and (3) is associated with a poor prognosis in TNBC breast cancer patients. Taken together, our results validate our enhancer identification pipeline and reveal that enhancers transcribed in breast cancer cells direct critical gene regulatory networks that promote pathogenesis.

Citing Articles

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