Treg/Th17 polarization by distinct subsets of breast cancer cells is dictated by the interaction with mesenchymal stem cells.

Breast cancer (BC) cells (BCCs) exist within a hierarchy beginning with cancer stem cells (CSCs). Unsorted BCCs interact with mesenchymal stem cells (MSCs) to induce regulatory T cells (Tregs). This study investigated how distinct BCC subsets interacted with MSCs to polarize T-cell response, Tregs versus T helper 17 (Th17). This study tested BC initiating cells (CSCs) and the relatively more mature early and late BC progenitors. CSCs interacted with the highest avidity to MSCs. This interaction required CXCR4 and connexin 43 (Cx43)-dependant gap junctional intercellular communication (GJIC). This interaction induced Treg whereas interactions between MSCs and the progenitors induced Th17 response. The increases in Treg and Th17 depended on MSCs but not CTLA-4, which was increased in the presence of MSCs. Studies with BM stroma (fibroblasts) and MSCs from the same donors, indicated specific effects of MSCs. In total, MSC-CSC interaction required CXCR4 for GJIC. This led to increased Tregs and TGFß, and decreased Th17. In contrast, late and early BCCs showed reduced formation of GJIC, decreased Treg and increased Th17 and IL-17. These findings have significance to the methods by which CSCs evade the immune response. The findings could provide methods of intervention to reverse immune-mediated protection and support of BC.

Moving from the laboratory bench to patients' bedside: considerations for effective therapy with stem cells.

Although stem cell therapy is not a new field, the field was limited to transplantation of hematopoietic stem cells. Such transplantation has provided invaluable information for the emerging field with new stem cells. Mesenchymal stem cells (MSCs) are an attractive source for therapy; reduced ethical concern, ease in expansion, as off-the-shelf stem cells. MSCs exert immune suppressive properties, providing them with the potential for immune suppressive therapy such as autoimmunity, asthma, allergic rhinitis and graft versus host disease. In addition, MSCs, as well as other stem cells, can be applied for bone and cartilage repair, cardiovascular disease, and neural repair/protection. The data thus far with MSCs are mixed. This review discusses the immune-enhancing properties of MSCs to explain the possible confounds of inflammatory microenvironment in the MSCs therapy. Although this review focuses on MSCs, the information can be extrapolated to other stem cells. The review summarizes the biology of MSCs, including multilineage differentiation potential, transdifferentiation capability, and immunological effects. We emphasize the key concepts that may predict the use of these cells in medicine, namely, the application of these cells from the bench to the bedside. Prospects on immunotherapy, neuroregeneration, and cardiovascular repair are used as examples of tissue repair.

Metastatic breast cancer cells in the bone marrow microenvironment: novel insights into oncoprotection.

Among all cancers, malignancies of the breast are the second leading cause of cancer death in the United States after carcinoma of the lung. One of the major factors considered when assessing the prognosis of breast cancer patients is whether the tumor has metastasized to distant organs. Although the exact phenotype of the malignant cells responsible for metastasis and dormancy is still unknown, growing evidence has revealed that they may have stem cell-like properties that may account for resistance to chemotherapy and radiation. One process that has been attributed to primary tumor metastasis is the epithelial-to-mesenchymal transition. In this review, we specifically discuss breast cancer dissemination to the bone marrow and factors that ultimately serve to shelter and promote tumor growth, including the complex relationship between mesenchymal stem cells (MSCs) and various aspects of the immune system, carcinoma-associated fibroblasts, and the diverse components of the tumor microenvironment. A better understanding of the journey from the primary tumor site to the bone marrow and subsequently the oncoprotective role of MSCs and other factors within that microenvironment can potentially lead to development of novel therapeutic targets.

Gap junction-mediated import of microRNA from bone marrow stromal cells can elicit cell cycle quiescence in breast cancer cells.

Bone marrow (BM) metastasis of breast cancer (BC) can recur even decades after initial diagnosis and treatment, implying the long-term survival of disseminated cancer cells in a dormant state. Here we investigated the role of microRNAs (miRNA) transmitted from BM stroma to BC cells via gap junctions and exosomes in tumor cell quiescence. MDA-MB-231 and T47D BC cells arrest in G(0) phase of the cell cycle when cocultured with BM stroma. Analyses of miRNA expression profiles identified numerous miRNAs implicated in cell proliferation including miR-127, -197, -222, and -223 targeting CXCL12. Subsequently, we showed that these CXCL12-specific miRNAs are transported from BM stroma to BC cells via gap junctions, leading to reduced CXCL12 levels and decreased proliferation. Stroma-derived exosomes containing miRNAs also contributed to BC cell quiescence, although to a lesser degree than miRNAs transmitted via gap junctions. This study shows that the transfer of miRNAs from BM stroma to BC cells might play a role in the dormancy of BM metastases.