Computerized image-intensified fluorescence microscopy has been used to quantify routing and subcellular concentrations of rhodaminated EGF (Rh-EGF) during its receptor-mediated endocytosis in two transfected NIH-3T3 cell lines expressing 2 X 10(5) and 1.5 X 10(6) receptors per cell, respectively. A series of images were digitized by focusing at different depths through the volume of a single cell. The digitized pictures were corrected for fluorescence photobleaching, and removal of out-of-focus fluorescence contributions by deconvolution using the point spread function of the microscope optics (Agard, D. A., and J. W. Sedat. 1980. Proc. Soc. Photo-Opt. Instr. Eng. 264:110-117) allowed automatic computer analysis of the time dependence of endosomal vesicle size and fluorescence intensity in a live cell and also enabled the study of isolated vesicles. An increase in the amount of fluorescence bound to the cell surface, either by increasing the number of receptors expressed per cell or the concentration of Rh-EGF in the incubation drop, yielded an increase in the total fluorescence of internalized vesicles without an increase in their number and area. The linear relation between fluorescence intensity and area for vesicles at different times indicates that EGF concentration is conserved. This is compatible with fusion of small vesicles to form larger ones. However, as endocytosis proceeds, a twofold increase in the slope of the fluorescence vs. area plots is observed for larger vesicles, suggesting that active sorting causes the EGF to be concentrated. Alternatively, this factor could be produced by cumulative fluorescence contributions from stacked membranes. Since coated pits are internalized independent of their occupancy with EGF receptor, we propose that endocytosis does not involve a mechanism specifically recognizing occupied receptor but is rather triggered by a global intracellular event.

Interactions between membrane proteins are believed to be important for the induction of transmembrane signaling. Endocytosis is one of the responses which is regulated by both intracellular and extracellular signals. To study such interactions, we have measured the lateral mobility and rate of endocytosis of epidermal growth factor receptor in three transfected NIH-3T3 cell lines (HER84, HER22, and HER82) expressing 2 X 10(4), 2 X 10(5) and 1.5 X 10(6) EGF-receptors per cell, respectively. Using rhodamine-labeled EGF (Rh-EGF) and rhodamine-labeled monoclonal anti-EGF-receptor antibody (Rh-mAb-108), we measured twofold decreases in the lateral diffusion coefficients for each approximately 10-fold increase in EGF-receptor concentration. Since steric effects cannot account for such dependence, we propose that protein mobility within the membrane, which is determined by the rate of motion between immobile barriers, decreases due to aggregate formation. The rate of endocytosis also decreases twofold between the HER84 (2 X 10(4) receptors/cell) and HER22 (2 X 10(5) receptors/cell) cell lines, suggesting that it is diffusion limited. The comparable rates of endocytosis of the HER82 and HER22 cell lines suggest that at high receptor density endocytosis may be limited by the total number of sites for receptors in coated-pits and by their rate of recycling.

The lateral diffusion coefficients of various epidermal growth factor (EGF) receptor mutants with increasing deletions in their carboxy-terminal cytoplasmic domain were compared. A full size cDNA construct of human EGF receptor and different deletion constructs were expressed in monkey COS cells. The EGF receptor mutants expressed on the cell surface of the COS cells were labeled with rhodamine-EGF, and the lateral diffusion coefficients of the labeled receptors were determined by the fluorescence photo-bleaching recovery method. The lateral mobilities of three deletion mutants, including a mutant that has only nine amino acids in the cytoplasmic domain, are all similar (D approximately equal to 1.5 X 10(-10) cm2/s) to the lateral mobility of the "wild-type" receptor, which possess 542 cytoplasmic domain of EGF receptor, including its intrinsic protein kinase activity and phosphorylation state, are not required for the restriction of its lateral mobility.