Abstract
In order to analyze the molecular mechanisms of cell adhesion during development, proteins on the surface of chick embryonic neural cells were compared with proteins released after placing these cells in culture. One of the components released into culture, F1 (molecular weight, Mr 140,000), was derived by proteolytic cleavage of a cell surface precursor with a molecular weight of at least 240,000. Another protein, F2, recovered from culture as a dimer (Mr 1110,000), appeared to be a product of limited proteolytic cleavage of F1. Cells in retinal tissue possessed a surface protein of Mr 150,000 that also appeared to be derived by limited proteolytic cleavage of the cell surface precursor. Antibodies to F2 interacted with determinants on the cell surface protein of Mr 150,000, and specifically prevented homologous and heterologous binding among dissociated retinal and brain cells. In contrast, antibodies to F1 failed to prevent cell-cell adhesion and did not crossreact with F2. These data suggest that the cell surface protein of Mr 150,000 generated by limited proteolysis is involved in adhesion of both retinal and brain cells. Cell-cell binding of both retinal and brain cells varied as a function of developmental age and brain cells acquired their binding properties at an earlier time than retinal cells. Similar results were obtained in experiments on the binding of retinal and brain cells of different ages to nylon fibres coated with antibodies to F2. The results of the molecular and cellular experiments are incorporated in a model for cell adhesion invoking both proteolytic activation and modulation of cell surface ligands.