Abstract 956: Systematic identification of the actionable kinase dependencies of chemotherapy-resistant triple-negative breast cancer

Triple-negative breast cancer (TNBC) accounts for approximately 15% of all breast cancer cases, with over 35,000 newly diagnosed women per year in the USA. TNBC patients are at high risk of recurrence, and neoadjuvant standard chemotherapy leads to pathologic complete response in only about 30% of patients. No targeted therapy has yet been conclusively established to improve outcome. The management of TNBC will significantly improve once mechanisms responsible for TNBC resistance to chemotherapies are identified. Here, we applied a new functional proteomic strategy to reveal which (dys)regulated phospho-signaling circuits are the effective dependencies of chemotherapy-resistant TNBC cells. The high-throughput kinase activity-mapping (HT-KAM) assay is our new screening technology to assess the catalytic activity of many kinases in parallel. HT-KAM relies on collections of biologic peptide probes that are computationally derived from PhosphoAtlas (Olow and Chen et al., Cancer Research 2016) and are physically used as combinatorial sensors to measure the activity of kinase enzymes in biologic extracts. The HT-KAM system provides access to a vast, untapped resource of meaningful measurements, whether readouts are interpreted irrespective of which enzymes phosphorylate which probes, or analyzed to convert global phospho-signatures into functional profiles of kinase activities. Kinome maps reveal how signaling networks are rewired by drug interventions in the context of different cellular backgrounds or exogenously mutated proteins/pathways, and provide insight into potentially targetable pathways. We previously successfully showed that the HT-KAM platform identifies new, actionable kinases responsible for intrinsic or acquired targeted-therapy resistance in BRAFV600E colorectal cancer cells and melanoma tumors from patients. To study TNBC, we used a 615-peptide sensor library that supports the mapping of >100 kinases and represents >900 functional kinase-substrate interactions relevant to tumor biology, and matches hundreds of druggable components of signaling circuits. We characterized the phospho-catalytic signatures of 10 TNBC cell lines, either untreated or treated with chemotherapeutic drugs (5-FU, carboplatin, doxorubicin) at IC50 concentrations. We also included a panel of 8 luminal BC cells. Based on our advanced preliminary data, we anticipate showing a comprehensive map of the oncogenic kinome of TNBC, and how it rewires its signaling network in respo