Enrichment for STRO‐1 expression enhances the cardiovascular paracrine activity of human bone marrow‐derived mesenchymal cell populations

The cardiovascular therapeutic potential of bone marrow mesenchymal stromal/stem cells (MSC) is largely mediated by paracrine effects. Traditional preparation of MSC has involved plastic adherence‐isolation. In contrast, prospective immunoselection aims to improve cell isolation by enriching for mesenchymal precursor cells (MPC) at higher purity. This study compared the biological characteristics and cardiovascular trophic activity of plastic adherence‐isolated MSC (PA‐MSC) and MPC prepared from the same human donors by immunoselection for stromal precursor antigen‐1 (STRO‐1). Compared to PA‐MSC, STRO‐1‐MPC displayed greater (1) clonogenicity, (2) proliferative capacity, (3) multilineage differentiation potential, and (4) mRNA expression of mesenchymal stem cell‐related transcripts. In vitro assays demonstrated that conditioned medium from STRO‐1‐MPC had greater paracrine activity than PA‐MSC, with respect to cardiac cell proliferation and migration and endothelial cell migration and tube formation. In keeping with this, STRO‐1‐MPC exhibited higher gene and protein expression of CXCL12 and HGF. Inhibition of these cytokines attenuated endothelial tube formation and cardiac cell proliferation, respectively. Paracrine responses were enhanced by using supernatant from STRO‐1Bright MPC and diminished with STRO‐1Dim conditioned medium. Together, these findings indicate that prospective isolation gives rise to mesenchymal progeny that maintain a higher proportion of immature precursor cells compared to traditional plastic adherence‐isolation. Enrichment for STRO‐1 is also accompanied by increased expression of cardiovascular‐relevant cytokines and enhanced trophic activity. Immunoselection thus provides a strategy for improving the cardiovascular reparative potential of mesenchymal cells. J. Cell. Physiol. 223: 530–540, 2010. © 2010 Wiley‐Liss, Inc.

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