Endothelial-mesenchymal interactions in vitro reveal molecular mechanisms of smooth muscle/pericyte differentiation.

Cell-cell interactions are central to vascular development. We have developed an in vitro system in which endothelial cells (EC) are co-cultured with 10T1/2 cells as smooth muscle cell (SMC)/pericyte precursors. 10T1/2 cells, in contact with EC, differentiate to SMC in a process mediated, at least in part, by a transforming growth factor-beta (TGF-beta)-mediated event. Co-culture with EC or TGF-beta treatment induced expression of SM22alpha, with co-culture inducing a significantly greater response. To dissect the molecular mechanisms of SMC/pericyte differentiation, reporter constructs containing the promoter for SM22alpha, a SMC-specific gene, were stably transfected into 10T1/2 cells and response to EC-co-culture and TGFbeta were compared. Co-culture with EC or TGFbeta treatment stimulated activity of a 441-bp SM22-alpha promoter to about the same extent, whereas co-culture induced the activity of a 3.7-kb promoter to about twice that of TGBbeta. Neutralization of TGFbeta in EC-10T1/2 co-cultures partially reduced the 3.7-kb SM22alpha promoter activity in 10T1/2 cells. Previously unidentified CArG and TCE elements near the 5' end of the promoter are responsible for full promoter activity. EC-mesenchymal contact appears to be required for full promoter activity of the SM22alpha gene in 10T1/2 and requires upstream CArG and TCE elements. The 3.7-kb SM22alpha promoter can direct expression of lacZ in vivo to SMC of the large vessels and the smaller intersomitic vessels. We have identified the expression of SM22alpha in pericytes of the retinal microvasculature in developing and remodeling vessels.