Slow scission of single synaptic vesicles by Dynamin at physiological temperature
Compensatory endocytosis is crucial for the presynapse to maintain a functional pool of fusion-competent vesicles. Slow Clathrin-mediated endocytosis has been widely regarded as the primary mechanism of retrieval but this has been challenged by competing Clathrin-independent endocytic models, most notably sub-second ultra-fast endocytosis, reported to be predominant at physiological temperature. Here, we sought to resolve the salience of the respective endocytic modes by using a purely presynaptic preparation, the Xenapse, amenable to total internal reflection fluorescence microscopy (TIRFM). While the role of Clathrin is in dispute, Dynamin is widely acknowledged to figure as the scission protein at the invaginated vesicle neck. Hence, we labelled the endogenous Dynamin I with EGFP by CRISPR-Cas9 techniques and visualized single synaptic Dynamin-mediated scission events at very high temporal resolution. This revealed only a single slow mode of Dynamin-dependent retrieval with a half time of ~ 9 seconds at physiological temperature. Cross-correlational analysis with fluorescently labelled Clathrin confirmed these Dynamin events to be Clathrin-dependent. We thereby affirm Clathrin-mediated endocytosis as the primary mode of compensatory retrieval.