Abstract 363: Dissecting CTC phenotypes: insights into mechanisms of breast cancer dormancy

Abstract

Abstract Uncovering phenotypes of patient-derived Circulating Tumor Cells (CTCs) offers the promise to dissect CTC heterogeneity in relation to metastatic competence, and to determine biomarkers of therapeutic utility for improved treatment. However, it is still unknown whether and how CTCs differ in their capacity to circulate while maintaining metastatic potential. Rates of CTC survival are highly variable, lasting less than few hours in some patients but in the order of decades in others. This can lead to many questions for yet unexplored mechanisms of CTCs responsible for dormancy, along with their properties and biomarker functionalities. We hypothesized that breast cancer CTC subsets possessing markers of pluripotency avoid organ arrest with extreme efficiency by the concomitant presence of quiescence and stem cell properties; and that expression of urokinase plasminogen activator receptor (uPAR) and beta-1 integrin (β1int), two biomarkers known to be directly implicated in tumor cell dormancy, are relevant in controlling the recurrence of breast cancer brain metastasis (BCBM). First, we isolated CTC subsets not expressing the epithelial cell adhesion molecule (EpCAM-negative CTCs), and characterized these subsets using DEPArrayTM, a new CTC platform able to dissect CTC heterogeneity at a single-cell level, thus interrogating the smallest functional unit of cancer. We captured EpCAM-negative/CD45-/CD44+/CD24- breast cancer CTC subsets that possessed combinatorial uPAR and β1int expression using multiparametric flow cytometry. Second, CTC subsets grew in vitro and were further characterized by DEPArrayTM. Markers expression was confirmed by confocal microscopy with subsets possessing a specific breast cancer gene profiling. Third, EpCAM-negative CTC subsets (uPAR+/β1int+ and uPAR-/β1int-) were interrogated for human embryonic stem cell markers by RT2 PCR arrays. Gene expression profiling was consistently distinct among uPAR+/β1int+ vs. uPAR-/β1int- CTC subsets and dependent upon patients’ BCBM status: expression of genes implicated in cell cycle progression (e.g., CDK42, CDK1), angiogenesis (e.g., FGF-2), and pluripotency (e.g., KLF4) was >30-fold higher than controls. Third, CTC subsets gene patterns isolated from patients with BCBM possessed RT2 profiles that were strikingly distinct from ones derived from patients with no BCBM. Of note, gene expression for RIF-1, a protein that counteracts actions of the breast cancer suppressor BRCA1, was highest (>50-fold) with distinct RIF-1 nuclear patterns in BCBM CTC subsets. In summary, we have linked EpCAM-negative uPAR/β1int CTC subsets and their properties to clinical BCBM; and will assess the therapeutic inhibition of uPAR/β1int CTC biomarkers on BCBM development and its timing. Deciphering the relevance of uPAR/β1int as key CTC biomarkers of dormancy vs. metastatic competence will elucidate CTC mechanisms responsible for BCBM onset. Citation Format: Sirisha Peddibhotla, Monika Vishnoi, Wei Yin, Yizhen Chen, Antonio Scamardo, David Hong, Dario Marchetti. Dissecting CTC phenotypes: insights into mechanisms of breast cancer dormancy. [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 363. doi:10.1158/1538-7445.AM2015-363