Tumor risk by tissue engineering: cartilaginous differentiation of mesenchymal stem cells reduces tumor growth.

OBJECTIVE: Implantation of autologous chondrocytes (AC) is a promising option for the treatment of cartilage defects, but problems with cell harvesting, dedifferentiation, or the donor age limit the clinical outcome. Mesenchymal stem cells (MSC) gain much interest because of their simple isolation and multipotential differentiation capacity along with their immunosuppressive properties. The latter might introduce tumor manifestation. The influence of undifferentiated and chondrogenically differentiated MSC or AC on tumor growth and metastasis formation was investigated in a murine melanoma model. METHODS: Allogeneic melanoma cells and either syngeneic MSC (C3H10T1/2, transduced with enhanced green fluorescent protein gene) or AC were co-injected at a distance of 3 cm into the contra lateral groins of five mice/group, and evaluated macroscopically and histologically after 4 weeks. RESULTS: Undifferentiated MSC migrated to the tumor site and induced strong tumor growth and metastasis formation. Even avital MSC promoted tumor growth and spreading, but insignificantly without detectable MSC at the tumor site. Chondrogenically differentiated MSC did not migrate and had a significantly lower impact on tumor growth and spreading; AC had no measurable influence on melanoma cells. CONCLUSIONS: Our data suggest that differentiation of MSC reduces MSC-dependent promotion of latent tumors and that native AC do not introduce any increased risk of tumor growth. The question of how far MSC should be differentiated prior to clinical application should be addressed in further studies.

Endoglin expression in metastatic breast cancer cells enhances their invasive phenotype.

Endoglin is a cell-surface adhesion protein as well as a coreceptor for transforming growth factor-beta (TGF-beta). It is located on endothelial and few other cells, but also found on certain tumor cells. Brain metastatic breast tumor cells derived from the MDA-MB-231 cell line heavily express endoglin in contrast to the corresponding parental ones. To clarify whether this determines their invasive phenotype, we compared their biological properties with endoglin-silenced brain-metastatic cells, low-expressing parental cells and these transfected with L- and S-endoglins, isoforms transducing or lacking TGF-beta signals. All L-endoglin-overexpressing cells were characterized by numerous invadopodia where endoglin was preferentially localized. Endoglin-expression resulted in elevated levels of the matrix metalloproteinases (MMP-1 and MMP-19) and downregulation of the plasminogen activator inhibitor-1. In Boyden-chamber and wound-healing assays, endoglin-overexpressing cells showed a considerably higher migration and chemotaxis to TGF-beta. In 3D spheroid confrontation assays between breast tumor cells and TGF-beta-secreting glioma cells, high L-endoglin-expressing cells invaded into the glioma-spheroids whereas low-endoglin-expressing cells dissociated in the culture; invasion was blocked by TGF-beta antibodies. In contrast to parental cells, endoglin-overexpressing cells invaded deeply into mouse brain slices. Thus, endoglin expression on tumor cells enhances their invasive character by formation of invadopodia, extracellular proteolysis, chemotaxis and migration.