Abstract: | The formation of intercellular adhesions by mouse 3T3 cells and their SV40-transformed derivatives is analysed by measuring the binding of pre-formed aggregates of these cells to cell layers or to a plastic substratum. The rationale for this procedure is to reduce the effects of cell dissociation on quantitative assessments of adhesive interactions. The fibroblasts within the aggregates retain the growth characteristics these cells show in monolayer culture. The proportion of aggregates binding is independent of the number of aggregates added and changes with time in a manner consistent with a first-order process, allowing the percent aggregates binding per unit time to serve as a parameter of intercellular adhesion. The rate of binding in homologous adhesive interactions is slower than in heterologous ones, binding in 3T3SV interactions is slower than in 3T3 interactions, and binding to cellular substrata is slower than to plastic. Binding of 3T3SV aggregates is readily distinguished from binding of 3T3 aggregates by the presence of a brief lag in binding rate, the formation of irregular projections from the bound aggregate, and a differential effect on binding rates of varying the temperature or of treating a single reactant with glutaraldehyde. Thus, there are quantitative and qualitative differences in the adhesive interactions of normal and transformed cells. The distinct binding properties of 3T3SV aggregates and the greater binding rates in heterologous interactions may be relevant to the invasive behavior of transformed cells in vivo. |