Recapitulation of mesenchymal condensation enhances in vitro chondrogenesis of human mesenchymal stem cells.

Mesenchymal condensation is a critical transitional stage that precedes cartilage formation during embryonic development. We hypothesized that "priming" hMSCs to recapitulate mesenchymal condensation events prior to inducing differentiation would enhance their subsequent chondrogenic properties. Our prior studies have suggested that exposing hMSCs to hypoxia (2% O(2)) induces condensation-like effects. We therefore assessed the effect of preconditioning for different time periods on the expression of condensation specific genes by growing hMSCs in expansion medium under different normoxic (20% O(2)) and hypoxic conditions for up to 2 weeks, and subsequently induced chondrogenesis of preconditioned hMSCs. The total cultivation time for each group was 4 weeks and the chondrogenic properties were assessed using gene expression, biochemical analysis, and histological staining. Our results demonstrated the benefits of preconditioning were both time- and oxygen-dependent. Condensation specific genes, SOX-9 and NCAM, were significantly up-regulated in hypoxic conditions at the end of 1 week. COL X and MMP13 expression was also lower than the normoxic samples at this time point. However, this group did not exhibit more efficient chondrogenesis after 4 weeks. Instead, hMSCs preconditioned for 1 week and subsequently differentiated, both under 20% O(2), resulted in the most efficient chondrogenesis. Interestingly, while hypoxia appears to positively enhance expression of chondrogenic genes, this did not produce an enhanced matrix accumulation. The results of this study emphasize the significance of considering the timing of specific cues in developing protocols for stem cell-based therapies and underscore the complexity in regulating stem cell differentiation and tissue formation.

The Role of Cytokines in Interactions of Mesenchymal Stem Cells and Breast Cancer Cells.

Mesenchymal stem cells, because of their high proliferation, differentiation, regenerative capacity, and ease of availability, have been a popular choice in cytotherapy. Mesenchymal Stem Cells (MSCs) have a natural tendency to home in a tumor microenvironment and act against it, owing to the similarity of the latter to an injured tissue environment. Several studies have confirmed the recruitment of MSCs by tumor through various cytokine signaling that brings about phenotypic changes to cancer cells, thereby promoting migration, invasion, and adhesion of cancer cells. The contrasting results on MSCs as a tool for cancer cytotherapy may be due to the complex cell to cell interaction in the tumor microenvironment, which involves various cell types such as cancer cells, immune cells, endothelial cells, and cancer stem cells. Cell to cell communication can be simple or complex and it is transmitted through various cytokines among multiple cell phenotypes, mechano-elasticity of the extra- cellular matrix surrounding the cancer cells, and hypoxic environments. In this article, the role of the extra-cellular matrix proteins and soluble mediators that act as communicators between mesenchymal stem cells and cancer cells has been reviewed specifically for breast cancer, as they are the leading members of cancer malignancies. The comprehensive information may be beneficial in finding a new combinatorial cytotherapeutic strategy using MSCs by exploiting the cross-talk between mesenchymal stem cells and cancer cells for treating breast cancer.