Rita Lampignano

Enrichment, Isolation and Molecular Characterization of EpCAM-Negative Circulating Tumor Cells

The presence of EpCAM-positive circulating tumor cells (CTCs) in the peripheral blood is associated with poor clinical outcomes in breast, colorectal and prostate cancer, as well as the prognosis of other tumor types. In addition, recent studies have suggested that the presence of CTCs undergoing epithelial-to-mesenchymal transition and, as such, may exhibit reduced or no expression of epithelial proteins e.g. EpCAM, might be related to disease progression in metastatic breast cancer (MBC) patients. Analyzing the neoplastic nature of this EpCAM-low/negative (EpCAM-neg) subpopulation remains an open issue as the current standard detection methods for CTCs are not efficient at identifying this subpopulation of cells. The possible association of EpCAM-neg CTCs with EpCAM-positive (EpCAM-pos) CTCs and role in the clinicopathological features and prognosis of MBC patients has still to be demonstrated. Several technologies have been developed and are currently being tested for the identification and the downstream analyses of EpCAM-pos CTCs. These technologies can be adapted and implemented into workflows to isolate and investigate EpCAM-neg cells to understand their biology and clinical relevance. This chapter will endeavour to explain the rationale behind the identification and analyses of all CTC subgroups, as well as to review the current strategies employed to enrich, isolate and characterize EpCAM-negative CTCs. Finally, the latest findings in the field will briefly be discussed with regard to their clinical relevance.

Toward a real liquid biopsy in metastatic breast and prostate cancer: Diagnostic LeukApheresis increases CTC yields in a European prospective multicenter study (CTCTrap): Toward a real liquid biopsy in metastatic breast and prostate cancer

Frequently, the number of circulating tumor cells (CTC) isolated in 7.5 mL of blood is too small to reliably determine tumor heterogeneity and to be representative as a “liquid biopsy”. In the EU FP7 program CTCTrap, we aimed to validate and optimize the recently introduced Diagnostic LeukApheresis (DLA) to screen liters of blood. Here we present the results obtained from 34 metastatic cancer patients subjected to DLA in the participating institutions. About 7.5 mL blood processed with CellSearch® was used as “gold standard” reference. DLAs were obtained from 22 metastatic prostate and 12 metastatic breast cancer patients at four different institutions without any noticeable side effects. DLA samples were prepared and processed with different analysis techniques. Processing DLA using CellSearch resulted in a 0–32 fold increase in CTC yield compared to processing 7.5 mL blood. Filtration of DLA through 5 μm pores microsieves was accompanied by large CTC losses. Leukocyte depletion of 18 mL followed by CellSearch yielded an increase of the number of CTC but a relative decrease in yield (37%) versus CellSearch DLA. In four out of seven patients with 0 CTC detected in 7.5 mL of blood, CTC were detected in DLA (range 1–4 CTC). The CTC obtained through DLA enables molecular characterization of the tumor. CTC enrichment technologies however still need to be improved to isolate all the CTC present in the DLA.

A Novel Workflow to Enrich and Isolate Patient-Matched EpCAMhigh and EpCAMlow/negative CTCs Enables the Comparative Characterization of the PIK3CA Status in Metastatic Breast Cancer

Circulating tumor cells (CTCs), potential precursors of most epithelial solid tumors, are mainly enriched by epithelial cell adhesion molecule (EpCAM)-dependent technologies. Hence, these approaches may overlook mesenchymal CTCs, considered highly malignant. Our aim was to establish a workflow to enrich and isolate patient-matched EpCAMhigh and EpCAMlow/negative CTCs within the same blood samples, and to investigate the phosphatidylinositol 3-kinase catalytic subunit alpha (PIK3CA) mutational status within single CTCs. We sequentially processed metastatic breast cancer (MBC) blood samples via CellSearch® (EpCAM-based) and via Parsortix™ (size-based) systems. After enrichment, cells captured in Parsortix™ cassettes were stained in situ for nuclei, cytokeratins, EpCAM and CD45. Afterwards, sorted cells were isolated via CellCelector™ micromanipulator and their genomes were amplified. Lastly, PIK3CA mutational status was analyzed by combining an amplicon-based approach with Sanger sequencing. In 54% of patients′ blood samples both EpCAMhigh and EpCAMlow/negative cells were identified and successfully isolated. High genomic integrity was observed in 8% of amplified genomes of EpCAMlow/negative cells vs. 28% of EpCAMhigh cells suggesting an increased apoptosis in the first CTC-subpopulation. Furthermore, PIK3CA hotspot mutations were detected in both EpCAMhigh and EpCAMlow/negative CTCs. Our workflow is suitable for single CTC analysis, permitting—for the first time—assessment of the heterogeneity of PIK3CA mutational status within patient-matched EpCAMhigh and EpCAMlow/negative CTCs.

Abstract 1532: The isolation of CTC from diagnostic leukapheresis

Introduction At present, the CellSearch system is the only validated method for the detection of circulating tumor cells (CTC) that has been cleared by the U.S. Food and Drug Administration. This system, designed for the enumeration of CTC in 7.5 mL of blood, detects CTC based on their expression of EpCAM and cytokeratins and negativity for CD45. However, the number of CTC that are detected in patients with metastatic carcinomas is in most cases too small to reliably determine tumor heterogeneity and to be representative as a ‘liquid biopsy’. Our aim is to identify and isolate a sufficient number of circulating tumor cells in virtually all metastatic cancer patients to enable their characterization and to represent a real-time liquid biopsy. For this purpose we used Diagnostic LeukApheresis (DLA) to increase the blood volume to be analyzed. We developed several techniques to isolate CTC from DLA to enable a multicenter comparison of CTC detection in DLA products. Methods DLAs were performed for ∼1 hour to obtain 40 mL of product containing ∼4 x10⁁9 mononuclear cells representing ∼1 liter of blood. Using CellSearch a maximum of 2 mL of DLA could be processed for EpCAM+ CTC (Fisher et al. doi: 10.1073/pnas.1313594110) and EpCAM- CTC (de Wit et al doi: 10.1038/srep12270). Using filtration through microsieves with 5 μm pores a maximum of 1.0 mL of DLA could be processed. To process 18 mL DLA product protocols were developed for leukocyte depletion using RosetteSep™ (StemCell Technologies, USA) and for EpCAM selection using an anti-EpCAM coated column (Leukocare AG). All enriched cell fractions were stained using CD45 PerCP, Cytokeratins PE and the nuclear dye DAPI, followed by fluorescence microscopy scanning and analysis. Results Leukocyte depletion using the RosetteSep™ CTC Enrichment cocktail was first optimized using small sample volumes (1 mL) spiked with cells from cancer cell lines. Depletion of leukocytes ranged from 3.1 to 3.9 logs with an average recovery of spiked cancer cells of 50-60%. Isolation of CTC expressing EpCAM was pursued using anti-EpCAM coated columns and optimized for selection and release of EpCAM expressing cells by passage of cells from cancer cell lines through the column resulting in 34-100% recovery. Both procedures were scaled up to enable processing of 18 mL of DLA. Leukocytes were depleted using RosetteSepTM by 3.1 - 3.9 logs whereas with anti-EpCAM columns only 1.7 - 1.8 logs depletion were reached. Using RosetteSepTM 21% and with the anti-EpCAM coated columns 2% of the tumor cells spiked into 18ml DLA were recovered. Conclusion Standard operating procedures were developed to isolate CTC in DLA9s from breast, prostate cancer and lung cancer patients for evaluation and comparison in the EU sponsored consortiums CTCTrap (www.utwente.nl/tnw/ctctrap/) and CANCER-ID (www.CANCER-ID.eu). Isolation of EpCAM expressing CTC using the anti-EpCAM coated columns will need further optimization before it can proceed to multicenter comparison. Citation Format: Kiki C. Andree, Anouk Mentink, Martin Scholz, Roland Kirchner, Rui P. Neves, Christiane Driemel, Rita Lampignano, Hans Neubauer, Dieter Niederacher, Tanja Fehm, Wolfram T. Knoefel, Johannes C. Fischer, Nikolas H. Stoecklein, Leon WMM Terstappen. The isolation of CTC from diagnostic leukapheresis. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 1532.