Single point mutation in the bin/amphiphysin/RVS (BAR) sequence of endophilin impairs dimerization, membrane shaping, and SRC homology 3 domain-mediated partnership.

International audienceBin/Amphiphysin/Rvs (BAR) domain-containing proteins are essential players in the dynamics of intracellular compartments. The BAR domain is an evolutionarily conserved dimeric module characterized by a crescent-shaped structure whose intrinsic curvature, flexibility and ability to assemble into highly ordered oligomers, contribute to inducing curvature of target membranes. Endophilins, diverging into A and B sub-groups, are BAR and SH3 domain-containing proteins. They exert activities in membrane dynamic processes such as endocytosis, autophagy, mitochondrial dynamics and permeabilization during apoptosis. Here, we report on the involvement of the third α-helix of endophilins A BAR sequence in dimerization and identify leucine 215 as a key residue within a network of hydrophobic interactions stabilizing the entire BAR dimer interface. With the combination of amino-terminal truncation retaining the high dimerization capacity of the third α-helices of endophilins A and leucine 215 substitution by aspartate (L215D), we demonstrate the essential role of BAR-sequence mediated dimerization on SH3 domain partnership. In comparison to wild type, full-length endophilin A2 heterodimers with one protomer bearing the L215D substitution, exhibit very significant changes in membrane-binding and shaping activities as well as dramatic decrease of SH3 domain partnership. This suggests that subtle changes in the conformation and/or rigidity of the BAR domain impact on both the control of membrane curvature and downstream binding to effectors. Finally, we show that expression, in mammalian cells, of endophilin A2 bearing the L215D substitution, impairs the endocytic recycling of transferrin receptors

Tethering of vesicles to the Golgi by GMAP210 controls LAT delivery to the immune synapse

International audienceThe T cell immune synapse is a site of intense vesicular trafficking. Here we show that the golgin GMAP210, known to capture vesicles and organize membrane traffic at the Golgi, is involved in the vesicular transport of LAT to the immune synapse. Upon activation, more GMAP210 interact with LAT-containing vesicles and go together with LAT to the immune synapse. Regulating LAT recruitment and LAT-dependent signaling, GMAP210 controls T cell activation. Using a rerouting and capture assay, we show that GMAP210 captures VAMP7-decorated vesicles. Overexpressing different domains of GMAP210, we also show that GMAP210 allows their specific delivery to the immune synapse by tethering LAT-vesicles to the Golgi. Finally, in a model of ectopic expression of LAT in ciliated cells, we show that GMAP210 tethering activity controls the delivery of LAT to the cilium. Hence, our results reveal a function for the golgin GMAP210 conveying specific vesicles to the immune synapse

Extracellular Vesicles Released by Allogeneic Human Cardiac Stem/Progenitor Cells as Part of their Therapeutic Benefit

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