RESUMEN
Cardiovascular development is the end result of a complex genetic program subject to regulation by signals transmitted between a cell and its extracellular environment. As cells encounter new extracellular matrices or establish new cell-cell interactions, new genes must be activated to accommodate the altered developmental situation within which the cell finds itself. This is likely reflected in a program of adhesion receptor and counter receptor expression on the surface of cells engaged in the morphogenesis. To understand the molecular basis of development, it is necessary to first determine if such a program exists and then to establish the role of various receptors and counter receptors in the particular morphogenetic process under investigation. To this end, we have initiated an investigation into expression of specific adhesion receptors during cardiovascular development in the mouse. Here, we demonstrate that platelet endothelial cell adhesion molecule (PECAM)-1 is an excellent marker for following vascular formation in the mammalian embryo. It is expressed during development in several alternatively spliced forms involving the cytoplasmic domain of the molecule. These forms differ in their ligand binding properties. Thus, a change in the cytoplasmic domain affects the folding of the molecule in such a way as to structurally alter the extracellular domain. Further, several receptors including the laminin receptor, the fibronectin receptor and a hyaluronic acid receptor, display specific expression patterns during heart development. These include differential expression in the endocardium and myocardium, down regulation during endocardial and myocardium, down regulation during endocardial cushion formation and cessation of expression in particular regions of the heart upon maturation. Interference with the function of one of these receptors (the fibronectin receptor) results in aberrant heart formation. These observations strongly support the concept that morphogenesis requires specific cell adhesion molecules that are expressed in precisely choreographed programs.