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Tumor biology is far more intricate than previously thought. Mounting evidence shows that tumor cells are more than a mere bulk of uncontrolled proliferating cells; rather, different neoplastic cells seem to perform different functions displaying high organization and hierarchy within the tumor1. Tumor cells are also in intimate communication with non-transformed cells: macrophages, fibroblasts, lymphocytes, adipocytes, endothelial cells, among other cells are all immersed in the scaffold proteins and polysaccharides that constitute the ECM. Numerous direct and indirect interactions are established between transformed and non-transformed cells and with the ECM, which exerts a powerful influence over the disease outcome2,3. In the specific case of BrC, it is particularly important to dissect the communication of BrC cells with TAMs, considering that TAMs have been found to play a critical role in the evolution of the tumor, increasing the risk of metastasis and of disease recurrence4,5.
To analyze intra-tumoral interactions and their possible outcomes, new 3D in vitro approaches have been developed based on the use of ECM extracts that provide a much more complex microenvironment, closer to the reality of tumor biology, in comparison to the conventional monolayer cell cultures in which the cells grow attached to plastic. Petersen and Bissell6 provided the first model of nonmalignant and malignant mammary epithelial cells cultured on a laminin-rich basement membrane and were the first to describe the 3D organotypic structures that discriminate nonmalignant human breast epithelial cells from their malignant counterparts. A decade later, the model developed by Debnath, Muthuswamy, and Brugge7,8,9 provided a valuable tool to elucidate the biological pathways compromised during malignant transformation of glandular acini, such as large acini formation due to uncontrolled proliferation, delocalization of tight junction proteins as evidence of impaired cell polarization, and loss of acini lumen as a result of cell resistance to anoikis, a type of programmed cell death that occurs in anchorage-dependent cells when they detach from the surrounding ECM. The models of Sameni, Jedeszko, and Sloane have focused on imaging proteolytic activity by cells, which is closely related to invasiveness, another crucial trait of tumor malignancy10,11,12. These models rely on protein matrices mixed with different fluorescence-quenched protein substrates (DQ-gelatin, DQ-collagen I, and DQ-collagen IV), in which fluorescent signals are indicative of the proteolytic degradation of collagen. 3D models are also used to study stem cell properties of both non-transformed and tumor cells, in which cell aggregates, also termed spheroids, can be cultured in suspension or in ECM-like proteins interrogating for mechanisms of cell differentiation, asymmetric cell division, cell-to-cell adherence, and cell motility13,14. Invasion assays allow testing of the intrinsic aggressiveness of the tumor and the identification of the molecules that serve as chemoattractants during the invasive process15. Overall, 3D models represent an affordable diversification of in vitro cell culture that more closely reflect normal and oncogenic tissue morphogenesis.
We have designed a 3D cell co-culture system based on the aforementioned models7,10,11, using both human commercial BrC cell lines of known aggressive potential (luminal and triple-negative types) and primary cells explanted from BrC patients. We first developed a model where either non-aggressive (MCF-7) or aggressive (MDA-MB-231) BrC cells were co-cultured with U937 monocytes in an extracellular matrix extract (ECME)-based 3D system that allowed direct cell-cell interactions. These co-cultures were used to determine how the communication between these two cell lineages influenced the transcription of a set of genes related to cancer aggressive behavior. A significant increase of cyclooxygenase-2 (COX-2) transcript was observed that coincided with an increased production of one of its products, prostaglandin E2 (PGE2), a finding that highlighted the role of inflammation in cancer progression. Increased transcription of MMP was also observed that correlated with greater collagen proteolysis when aggressive MDA-MB-231 cells were co-cultured with U937 monocytes in DQ-Collagen IV-containing cultures. Of note, our co-cultures did not support the assumption that cell-cell interaction mechanisms are needed for collagen degradation. It rather suggested that communication between the two cell lineages was mediated by secreted molecules. Furthermore, the supernatants harvested from these co-culture assays contained soluble factors that disorganized glandular acini formed by non-transformed MCF-10A cells13. It was found that aggressive and primary BrC cells secreted elevated levels of monocyte chemotactic molecules MCP-1, GM-CSF, and RANTES. Thus, we outlined a 3D culture in which cells were separated in cell culture inserts to prevent cell-cell interactions. These cultures were used to address the indirect communication between BrC cells and monocytes. For these assays, non-aggressive and aggressive commercial BrC cell lines and primary BrC cells, and three different types of human monocytes: commercial U937 and THP-1 cells, and primary monocytes (PMs) isolated from peripheral blood of healthy donors (all monocytes were used in a non-activated state) were used. Increased concentrations of inflammatory cytokines IL-1β and IL-8 were observed to be enriched in co-culture. Similarly, it was found that MMP-1, MMP-2, and MMP-10 were also increased in the BrC cells-monocyte co-cultures, and thus reinforcing previous findings14. In this manuscript, a point-by-point workflow of primary BrC cells isolation and testing in 3D cultures is presented along with representative results. This work constitutes a good example of the great potential that in vitro 3D cell systems provide to interrogate specific aspects of tumor biology.