“Stop and go” kinetics of receptor movements induced by anti-Ig or antigen on individual lymphocytes

Abstract

Serial observations were conducted on the time course of surface immunoglobulin (Ig) redistribution (capping) on individual mouse spleen lymphocytes. Capping of surface Ig by anti-Ig fluorescein and also antigen-induced capping of receptors on specific sheep erythrocyte antigen-binding cells were observed and the times required for individual cells to clear 90 and 180 ° of their circumference were recorded. There were striking differences between individual cells in both the onset and duration of receptor movements. Although the number of cells achieving complete clearing of first and second quadrants in successive time intervals declined, there was no correlation between the time required by a cell to clear the first quadrant and the time required by the same cell to clear the second quadrant. Thus, instead of observing gradual progressive migration of marker toward one pole of each individual cell at a rate resembling that of the whole population, we observed grossly discontinuous receptor movements, characterized by brief major shifts in receptors followed by a period of relative stability. Capping is thus viewed as a series of discrete contractile events related to the activity of membrane-associated cytoskeletal elements rather than a manifestation of “membrane flow”.