Retrofusion of intralumenal MVB membranes parallels viral infection and coexists with exosome release

The endosomal system constitutes a highly dynamic vesicle network used to relay materials and signals between the cell and its environment. (1)Once internalized, endosomes gradually mature into late acidic compartments and acquire a multivesicular body (MVB) organization through invagination of the limiting membrane (LM) to form intraluminal vesicles (ILVs). (2)Cargoes sequestered into ILVs can either be delivered to lysosomes for degradation or secreted following fusion of the MVB with the plasma membrane. (3)It has been speculated that commitment to ILVs is not a terminal event, and that a return pathway exists, allowing back-fusion or retrofusion of intraluminal membranes to the LM.(4) The existence of retrofusion as a way to support membrane equilibrium within the MVB has been widely speculated in various cell biological contexts, including exosome uptake(5) and major histocompatibility complex class II (MHC class II) antigen presentation. (6-9) Given the small physical scale, retrofusion of ILVs cannot be measured with conventional techniques. To circumvent this, we designed a chemically tunable cell-based system to monitor retrofusion in real time. Using this system, we demonstrate that retrofusion occurs as part of the natural MVB lifestyle, with attributes parallel to those of viral infection. Furthermore, we find that retrofusion and exocytosis coexist in an equilibrium, implying that ILVs inert to retrofusion comprise a significant fraction of exosomes destined for secretion. MVBs thus contain three types of ILVs: those committed to lysosomal degradation, those retrofusing ILVs, and those subject to secretion in the form of exosomes.

Automated summary

The endosomal system is a dynamic vesicle network for material and signal exchange between the cell and its environment. The cargoes in endosomes can be either degraded or secreted, with the possibility of retrofusion of intraluminal membranes back to the limiting membrane. This retrofusion process supports membrane equilibrium within the multivesicular body (MVB).