Ca2+ Triggers a Novel Clathrin-Independent but Actin-Dependent Fast Endocytosis in Pancreatic Beta Cells

The existence of clathrin-independent recycling of secretory vesicles has been controversial. By combining patch-clamp capacitance recording, optical methods and specific molecular interventions, we dissect two types of mechanistically different endocytosis in pancreatic β cells, both of which require GTP and dynamin. The fast one is a novel clathrin-independent but actin-dependent endocytosis that is triggered by high cytoplasmic Ca2+ concentration ([Ca2+]i). Large fluorescent dextran (10 nm in diameter) was able to be internalized by this pathway, indicating that it was not likely to be ‘kiss and run’. The slow endocytosis is a clathrin-dependent process in which actin plays a complementary role. For the first time, we show that the rate constants for both types of endocytosis exhibit supralinear dependence on increase in [Ca2+]i. Compared with the slow endocytosis, higher [Ca2+]i level was required to fully accelerate the fast one, indicative of distinct Ca2+ sensors for different endocytosis. In the end, we show that physiologically relevant stimulation induces clathrin-independent endocytosis in intact β cells, implying that it may contribute to the normal recycling of secretory vesicles in vivo.