To explain the robust results obtained by Bai et al. (2010), it is also possible that the BAR domain may promote some see more form of clathrin-independent endocytosis, considering that rescue experiments with exogenous proteins are likely to result in at least some degree of overexpression ( Bai et al., 2010).
Although our data and previous studies emphasize the major similarity of the defects produced by the absence of either endophilin or synaptojanin 1, one notable difference was observed. In contrast to what we have found here at endophilin TKO synapses, the amplitude of mEPSCs was increased relative to control at synaptojanin 1 KO synapses. Interestingly, a similar discrepancy was observed in Drosophila, in which other properties of endophilin and synaptojanin Selleck BMS 354825 mutant synapses were similar ( Dickman et al., 2005). Determining whether
this discrepancy is due to a different impact of the lack of endophilin and of synaptojanin on postsynaptic functions is an interesting question for future investigations. Studies of endophilin’s bilayer-deforming properties had suggested that it helps bend the membrane at CCPs, perhaps starting early in the process and then shaping their neck (Farsad et al., 2001, Gallop et al., 2006 and Ringstad et al., 1999). However, imaging data have demonstrated that endophilin is recruited only shortly before fission, when most of the curvature of the bud and of its neck is already acquired (Ferguson et al., 2009 and Perera et al., 2006). Proteins suited to bind curved bilayers may function as curvature inducers or sensors depending on several Metalloexopeptidase parameters, including their concentration, bilayer chemistry, and a variety of regulatory mechanisms (Antonny, 2006). Both curvature-sensing and -generating properties of endophilin were directly demonstrated (Chang-Ileto et al., 2011, Cui et al., 2009, Farsad et al., 2001 and Madsen et al., 2010). Curvature sensing may predominate in the initial recruitment of endophilin at CCP necks, although additional polymerization may facilitate curvature stabilization and neck elongation. Our observation that the endophilin
BAR construct is targeted to the CCPs supports this possibility. Consistent with this scenario, absence of the endophilin homolog Rvs167 in yeast leads to endocytic invaginations that bounce back and forth and often do not proceed to fission, suggesting a role of Rvs167 in stabilizing a preformed invagination (Kaksonen et al., 2005). An action of endophilin before fission, even if one of its main effects becomes manifested only after fission, also agrees with the finding that a plasma-membrane-tethered endophilin-chimeric construct rescued the absence of endophilin in worms (Bai et al., 2010). The role of Hsc70 and its cochaperone auxilin in the disassembly of the clathrin lattice is well established (Massol et al., 2006, Xing et al., 2010 and Yim et al., 2010).