PD03-07: Breast Cancer Heterogeneity and Treatment Resistance: Clues from Metaplastic Tumors.

At late stage, nearly all breast cancers are heterogeneous and refractory to treatment, like metaplastic breast cancer is at an early stage. These rare carcinomas are highly aggressive and de-differentiated. They are enriched for mesenchymal and stem cell features and essentially fail current therapies. As metaplastic tumors provide a time-compressed picture of breast cancer progression early on, understanding these tumors will yield insight into mechanisms that drive breast cancer into advanced stages and treatment resistance. To investigate a genetic basis for heterogeneity in metaplastic breast cancer, we established a progression model comprising three cell lines. The cell lines were derived from a primary tumor, a local recurrence and a pleural effusion of a 40-year old patient. The primary tumor was a stage III invasive metaplastic, triple negative, inflammatory breast cancer, resected after neoadjuvant chemotherapy (capecitabine and taxotere, then adriamycin and one cycle of bevacizumab). The local recurrence, biopsied seven months post mastectomy, developed after the patient received adjuvant carboplatin and gemcitabine for 3 cycles and then radiation to the chest wall. At this time, the patient had lung metastases and was treated with taxol and bevacizumab yielding a mixed response. Local invasive growth continued and a malignant pleural effusion developed four months later. Analyzing the genetic and molecular characteristics of this progression model in vitro, its tumorigenicity and metastasis in vivo, and interrogating lead findings in a growing collection of metaplastic tumors helps us to dissect the genetic heterogeneity in breast cancer, and potentially to identify the cell types that drive disease progression and treatment resistance. Our gene expression analyses and genomic evaluations identified epithelial to mesenchymal transition (EMT) as a key characteristic in the progression and treatment resistance of this cancer. Major changes in cytoskeletal genes, chemokines and their receptors, amplification of drug transporter proteins, metalloproteinases and matrix proteins seen with increasing motility and invasiveness along with recruitment of host inflammatory responses in the in vivo model, loss of chromosomal regions harboring known and putative tumor suppressors, and deletions of genes encoding proteins for metabolic inactivation of sex hormones in the breast tissue, along with specific loss of clusters of desmosomal genes are guiding our understanding of metaplastic breast cancer progression. The results provide insight into the development, the extremely invasive nature, and treatment resistance of these tumors. Our collaborative network of clinicians, pathologists, translational genomic researchers and bioinformatics specialists will enable us to identify and prioritize genetic events as disease drivers, prognostic biomarkers of disease progression, and determinants of treatment resistance. Our goal is to identify molecular and functional targets for effective therapy and evaluate them in the clinic. Lessons learned from metaplastic breast cancer will improve our understanding of breast cancer progression in general, and could translate into effective treatments for advanced breast cancer where current standard of care is failing. Citation Information: Cancer Res 2011;71(24 Suppl):Abstract nr PD03-07.