Analysis of the Plasticity of Circulating Tumor Cells Reveals Differentially Regulated Kinases During the Suspension‐to‐Adherent Transition

ABSTRACT Background Research on circulating tumor cells (CTCs) offers the opportunity to better understand the initial steps of blood‐borne metastasis as main cause of cancer‐related deaths. Here, we have used the colon cancer CTC‐MCC‐41 and breast cancer CTC‐ITB‐01 lines, which were both established from human CTCs as permanent cell lines as models to further study CTC biology with special emphasis on anchorage‐independent survival and growth. Methods and Results Both cell lines showed a marked intrinsic plasticity to switch between suspension and adherent in vitro growth, in 2D adherent culture conditions, and established an equilibrium of both growth patterns with predominant adherent cells in the CTC‐MCC‐41 line (77%) and suspension cells in the CTC‐ITB‐01 line (85%). Western blot analysis revealed a higher expression of pERK1/2 in CTC‐ITB‐01 adherent cells compared to the suspension counterpart that suggested the involvement of kinases in this process. Subsequent functional kinome profiling identified several serine/threonine as well as tyrosine kinases that were differentially regulated in adherent and suspension CTCs. In the adherent cells of the breast cancer line CTC‐ITB‐01 the activity of MSK1, Src family kinases and the PKG family was increased compared to the suspension counterpart. In adherent cells of the colorectal CTC‐MCC‐41 line, an increased activity of TYRO3 and JAK2 was detected, whereas p38 MAPK was strongly impaired in the suspension CTC‐MCC‐41 cells. Some of the regulated kinases, which include the Src family, TYRO3, MSK1, JAK2 and p38 MAPK, have been associated with crucial cellular processes including proliferation, migration and dormancy in the past. Conclusions The investigated CTC lines exhibit a high plasticity, similar to the concept of ‘adherent‐to‐suspension transition (AST)’ that was recently suggested as a new hallmark of tumor biology by Huh et al. Moreover, we identified differentially regulated kinome profiles that may represent potential targets for future studies on therapeutic interventions.