Project description:Breast tumors are characterized into different subtypes based on their surface marker expression, which affects their prognosis and treatment. For example, triple negative breast cancer cells (ER-/PR-/Her2-) show reduced susceptibility towards radiotherapy and chemotherapeutic agents. Poly (ADP-ribose) polymerase (PARP) inhibitors have shown promising results in clinical trials, both as single agents and in combination with other chemotherapeutics, in several subtypes of breast cancer patients. PARP1 is involved in DNA repair, apoptosis, and transcriptional regulation and an understanding of the effects of PARP inhibitors, specifically on metabolism, is currently lacking. Here, we have used NMR-based metabolomics to probe the cell line-specific effects of PARP inhibitor and radiation on metabolism in three distinct breast cancer cell lines. Our data reveal several cell line independent metabolic changes upon PARP inhibition, including an increase in taurine. Pathway enrichment and topology analysis identified that nitrogen metabolism, glycine, serine and threonine metabolism, aminoacyl-tRNA biosynthesis and taurine and hypotaurine metabolism were enriched after PARP inhibition in the three breast cancer cell lines. We observed that the majority of metabolic changes due to radiation as well as PARP inhibition were cell line dependent, highlighting the need to understand how these treatments affect cancer cell response via changes in metabolism. Finally, we observed that both PARP inhibition and radiation induced a similar metabolic response in the HCC1937 (BRCA mutant cell line), but not in MCF-7 and MDAMB231 cells, suggesting that radiation and PARP inhibition share similar interactions with metabolic pathways in BRCA mutant cells. Our study emphasizes the importance of differences in metabolic responses to cancer treatments in different subtypes of cancers.
Project description:We have utilized ChIPseq to identify the ER-beta cistrome in ER-beta expressing MDA-MB-231 triple negative breast cancer cells. ER-beta has been identified as a tumor suppressor in breast cancer and recent reports have demonstrated that ER-beta protein is detectable at moderate to high levels in approximately 30% of triple negative breast tumors. Increased expression of ER-beta in triple negative breast cancer has also been reported to be associated with improved recurrence-free survival. Treatment of ER-beta expressing triple negative breast cancer cells with estrogen, or the ER-beta selective agonist, LY500307, results in decreased cell proliferation, invasion and migration. To begin to identify the molecular mechanisms by which ER-beta elicits tumor suppressive effects in triple negative breast cancer, we performed ChIPseq studies and identified the genome-wide binding sites for ER-beta following exposure to 1nM estrogen or 10nM LY500307 for 3 hours. Over 28,000 and 10,000 unique ER-beta binding sites were identifed in response to these two ligands respectively. The top transcription factor motifs identified under both treatment conditions were estrogen response elements and AP1 response elements. The majority of ER-beta binding sites were found at enhancer regions located within introns or intergenic chromatin regions followed by gene promoters.