Abstract 3398: Development of a mass spectrometry based antibody-drug conjugate biomarker panel

Abstract

Abstract Background: Antibody-Drug Conjugates (ADCs) are poised to become an extremely important class of therapeutics in oncology. By conjugating cytotoxic payloads to antibodies that target proteins found primarily on cancer cells, ADCs represent a novel mechanism for directing extremely toxic small molecules specifically to tumor cells. Due to the unique mechanism of ADCs, patient selection should involve screening not only for the presence of the antibody target, but also screening for the presence of any markers of resistance or response to the payload. Several proteins, such as multi-drug effluxers and tubulin-beta 3, have been implicated in resistance to small molecule cytotoxins and microtubule inhibitor drugs. OncoPlex Diagnostics has built a multiplexed ADC biomarker panel that simultaneously quantifies the levels of the antibody target and putative resistance markers for several known payloads, such as maytansinoids, auristatins and taxanes, as well as response markers for the topoisomerase inhibitor payloads SN-38 and doxorubicin. Methods: Liquid Tissue-Selected Reaction Monitoring (LT-SRM) is a multiplexed, quantitative method that uses mass spectrometry to quantify proteins based on a unique sequence of amino acids, and thus does not have the same limitations as traditional antibody-based, semi-quantitative protein detection methods, such as immunohistochemistry. We developed a LT-SRM assay to quantify protein levels of EGFR, FRalpha, Her2, CD30 and Mesothelin (antibody targets) and MCL1, MDR, MRP1, tubulin-beta3, Topo1 and Topo2a (payload response and resistance markers) simultaneously from FFPE biopsies. Calibration curves for all the proteins in the ADC panel are linear over 5-orders of magnitude, with limits of detection for each analyte between 25 and 400 amol/ug of tissue. Results: Analysis of FFPE tumor tissues show a broad range of expression for the ADC proteins, with some tissues showing no detectable levels of some payload markers. Clinical analysis of FRalpha showed a range of expression from <LOD to 13500 amol/ug. An examination of Her2 positive tissue showed a wide range of Her2 expression (over 20-orders of magnitude), as well as a wide range of expression for the payload markers. The differences seen in the payload markers suggest differing responses to Her2-targeted ADCs, independent of Her2 levels, and indicate that different patient populations might respond better to different payloads, depending on tumor biology. Conclusions: The OncoPlexDx ADC panel can determine of a cutoff for expression levels of the antibody-target protein necessary for ADC response as well as identify markers of payload response or resistance to further understand how these markers affect therapeutic efficacy. This panel can be used to predict which patients will derive the most benefit from ADC therapy based on the specific biology of their tumor. Citation Format: Adele Blackler, Wei-Li Liao, Sheeno Thyparambil, Eunkyung An, Fabiola Cecchi, Marlene Darfler, Todd Hembrough, Jon Burrows. Development of a mass spectrometry based antibody-drug conjugate biomarker panel. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 3398. doi:10.1158/1538-7445.AM2015-3398