Circulating tumor cells (CTCs) are rare and heterogeneous cells found in the peripheral blood of cancer patients. They are supposed to be a central component of metastatic dissemination and have been correlated with prognosis, progression-free survival, and treatment efficacy in different solid tumors (1, 2). Despite CTC significance, studies conducted on them still present considerable issues. In particular, regarding to how CTCs should be investigated and to their actual metastatic competence and tumor heterogeneity reflecting dissimilar cancer cell subpopulations. Importantly, CTCs’ clinical utility has not been demonstrated and they cannot be utilized to guide therapeutic decisions. As reviewed by others (3), recent and currently ongoing clinical trials are trying to determine the predictive role of CTCs, but they are apparently failing to support definitive conclusions. Nevertheless, the results of these trials could shed a light on the real possibilities of CTCs. In our opinion, CTC troubleshootings will depend on what scientific community will explore about CTCs and the metastatic process. Only a deeper insight in base knowledge about CTCs and their role in tumor biology may help us in overcoming such hurdles.
A huge amount of efforts have been made to solve these problems. In the last decade, a number of technical solutions have been evaluated to study CTCs. Based on biological and/or physical properties (4), each approach owns strengths and weaknesses. Up to now, the only device that has reached a major confirmation by clinical evidence is the CELLSEARCH® System (5). Despite the pivotal results obtained with this system (6–9), its detection approach, based on epithelial markers only, fails to reflect all the potential CTC subpopulations, e.g., EpCAM-negative cells (10). Antigen-independent approaches that allow the identification of EpCAM-negative cells also (11–13) could eliminate the risk of underestimation of the dissimilar CTC populations; however, it could increase the risk of unspecific selection (14). Although the lack in technical standardization still hinders CTCs’ full translation in the clinical practice, these alternative methods could shed a light on the true nature of CTCs and pave the way to a clearer window into cancer biology and metastasis. In our opinion, in order to get further key insights into tumor aggressiveness, metastatic competence, heterogeneity, and resistance to treatment, we have to look back more deeply at base research, i.e., CTC-related epithelial–mesenchymal transition and stemness, CTC subpopulation/heterogeneity, and to CTC preclinical ex vivo studies.
It seems reasonable that CTC subsets and progression of metastasis could be enabled by EMT or by an EMT-like process (15). However, the involvement of EMT in metastatic dissemination is still debated (16, 17). It has been observed that EMT is not always needed for tumor cell motility (13) and recently, EMT was reported to be dispensable for metastasis, while contributing to chemoresistance (18, 19). Notably, not all the steps of EMT are necessary to establish an invasive phenotype of cancer cells (14). It has been postulated that EMT could be connected to cancer stemness (20) and that CTC population may comprise a subset of cells, with self-renewal, multi-potency, and tumor-initiating capabilities. Taking together, these aspects suggest two current needs for the CTC-research field. First, a detection approach more comprehensive than those established so far, able to catch all the different CTC subpopulations. Second, the necessity of a more in-depth analysis into the EMT regulatory networks during cancer initiation and progression (21). This approach will likely reveal the actual role of CTC subsets as “key players” involved in metastasis onset and progression (i.e., metastases-initiating CTCs), paving the way to innovative treatment regimens. Important technological improvements achieved in the field of genetic, genomic and transcriptomic analysis, as whole genome amplification (WGA), whole transcriptome amplification (WTA) for single cell, digital PCR (dPCR), and next-generation sequencing (NGS), could help to improve CTC research field and have to be accurately taken into consideration. Serial CTC molecular tumor profiling can facilitate the detection of primary (22) or acquired mechanisms of resistance to therapy, such as the emergence of ESR1 mutations in breast cancer or AR splicing variants in prostate cancer in response to targeted therapy (23, 24).
These last data indicate that monitoring regulatory networks and heterogeneity of CTCs, although still quite hampered by methodological issues, will offer significant clinical information about cancer progression, potential new therapeutic targets, and tumor sensitivity or resistance to therapy (25–29).
Circulating tumor cell population likely contains metastasis precursors, and their ex vivo culture represents a philosopher’s stone of translational-oncology research. Ex vivo culturing of CTCs may provide a powerful model of the metastatic cascade in basic research and a pivotal test for drug susceptibility/resistance in translational research (30).
In the last years, the CTC world’s leading groups had signed pioneering studies about ex vivo culturing of CTCs. Ex vivo CTC studies can be grouped as canonical in vitro culturing (11, 13, 30) and mice-incubator investigations (31, 32). Long-term CTC in vitro culturing were performed for the first time by the Marchetti’s and Maheswaran’s labs (11, 30), from blood of metastatic breast cancer patients. Zhang et al. detected and established CTC subpopulations targeted for brain metastases (11). These CTC cell lines were EpCAM negative, positive for a robust stem cell marker as ALDH1 and for Notch1, HER2, EGFR, and HPSE. Notably, CELLSEARCH® corresponding analyses revealed few or any “conventional” CTCs. Yu et al. generated CTC cell lines from consecutive single-patient blood draws (30). All the CTC cell lines were able to generate metastases in xenograft model proving their tumorigenic capability. Interestingly, both studies utilized a stem cell culture dedicated medium, strengthening the idea of the stem-like nature of CTCs. A CTC cell line was established from a metastatic colon cancer patient also (33). These tumorigenic cells owned the chromosomal aberrations observed in the primary tumor and were positive for ALDH and CD133 (stemness features).
A different ex vivo approach implied to expand CTCs into a xenograft model as a living “incubator.” This strategy consisted of a direct inoculation of enriched CTCs into immunodeficient mice without any in vitro passage. In an early study of Pretlow et al. (31), authors inoculated nucleated cells from 9 to 21 ml of blood from 14 treatment-refractory metastatic cancer patients (colon and prostate) into immunodepressed mice. Despite the lack of a CTC enrichment step, 3 out of 14 mice developed lung metastases. A more refined study was recently reported by Baccelli et al. (32). In this study, erythrocytes deprived blood from 3 out of 110 metastatic cancer patients formed different metastases (lung, liver, and bone) in recipient mice. Hodgkinson et al. (34) inoculated enriched CTCs in immunocompromised mice and established xenopatient models from six small-cell lung cancer patients. Xenopatient models mirrored patient responses to chemotherapy.
All these pioneering studies in ex vivo culturing of CTCs demonstrated how CTC basic research is important and necessary, from discovering specific genetic signature of resistance to mirroring patient response to therapy. More studies, however, have to be undertaken to expand our knowledge on CTC and translate their promises from bench to bedside.
A further critical matter that should be clarified is how many CTCs detected in few milliliters of blood may be representative of all relevant genetic and phenotypic heterogeneity of cancer cell with metastatic aptitude. A robust increase in the volume of blood analyzed will advantageously raise the number of detected CTCs, enabling the study of a higher more representative and informative number of tumor cells (35, 36).
In conclusion, we think that future base research studies on CTCs will be pivotal to move forward this field of investigation at both the preclinical and clinical levels. In order to progress toward the clinical utility of CTCs, biological data and technological improvements should be kept in mind and thoughtfully considered. To unravel CTC biology and to demonstrate their clinical value, a fully comprehensive CTC analysis approaches have to be achieved.
These advanced analyses combine: larger screened blood volume followed by CTC functional studies and deep next-generation “-omic” analysis. These steps could unveil CTC genetic heterogeneity, markers of resistance to therapy and identify actual metastases initiating CTCs. A new explanation of CTC at cellular and molecular level in both early and metastatic cancer stages (37) is now mandatory.
Author Contributions
GG, PF, and FF were jointly responsible for writing the paper and agreed to its submission.
Conflict of Interest Statement
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
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