One of the nine clones failed to differentiate, probably due to senescence. The clonal assay showed that the CD90− hmrMSCs Roscovitine contained single progenitor

cells with multiple lineage differentiation capabilities. The fact that certain clones were not tripotent suggested that other, more committed progenitors are present in this population. The multipotent differential potential of the CD90− cells was confirmed by qPCR. Bone morphogenetic proteins (BMPs) play a critical role in the commitment of MSCs and the induction of osteoblastic activity [38] and [39]. To assess the osteogenic differentiation potential, we used BMP9, the most potent osteogenic BMP [40], which efficiently induces the osteogenic program of mouse progenitor muscle resident stromal cells [2] and for which a role in the AZD6244 in vivo development of human HO was proposed [29]. BMP9 significantly increased the expression of the

osteogenic markers SP7 and DLX5 in CD90− cells compared to unstimulated cells (Fig. 3A). The chondrogenic potential of the CD90− population was also verified under standard chondrogenic conditions using TGFβ, a known chondrogenic inductor [41]. Compared to the unstimulated control, TGFβ significantly increased cartilage-specific collagen II (Col2A1) and proteoglycan core aggrecan (ACAN) gene expression within 3 and 14 days, respectively (Fig. 3B). We also assessed the white and brown adipogenic potentials of the CD90− population. Unlike white adipocytes, brown adipocytes are specialized in adaptive thermogenesis in which UCP1 plays a key role and is a specific marker of this cell type [31] and [32]. Since UCP1-expressing adipocytes are present in human HO (Fig. 1F) and since the CD90− hmrMSC population has a strong adipogenic potential in vitro ( Fig. 2B), we determined

whether Sulfite dehydrogenase this population could give rise to white adipocytes or UCP1-expressing brown adipocytes. Human adipose-derived stem cells can differentiate into white or brown adipocytes depending on the length of rosiglitazone (ROS) treatment in adipogenic differentiation medium [42]. We used this approach with the CD90− cells to drive white and brown adipocyte formation. Gene expression analyses revealed that the levels of the general adipogenic factors FABP4, ADIPOQ and PPARγ were higher in the white (ROS 3d) and brown (ROS 14d) adipogenic conditions than in the unstimulated control ( Fig. 3C). At day 14, brown adipocyte marker UCP1 mRNA levels were significantly higher in the cell preparations treated to induce white (ROS 3d) and brown (ROS 14d) adipocyte formation (38- and 4900-fold, respectively) than in the unstimulated control ( Fig. 3C). The increase in UCP1 expression was confirmed by immunofluorescence and Western blotting ( Figs. 3D, E).