Exophers are components of mammalian cell neurobiology in health and disease

Maintenance of cellular homeostasis is critically important for the survival of cells and organisms. Degradation and recycling of biomolecules and whole organelles is an essential mechanism for maintaining cellular homeostasis. The main systems responsible for these processes are the ubiquitin-proteasome system and autophagy-lysosome pathway. Another mechanism was reported in c. elegans —formation of large, membrane-enclosed projections called “exophers,” into which cells direct debris and toxic protein aggregates ¹ . Exophers were shown to act as large, temporary disposal compartments that disconnected from the cells within several hours. Here, we report the discovery of exophers in the mammalian brain, including the brains of humans and mice. Similar to those described in nematodes, the mammalian exophers appear to emanate from the cell body, initially connected by a nanotube, and eventually disconnect. Rare, innate exophers were found in healthy human brain and primary neurons from wild-type mice, presumably mediating transfer of large cargo between cells. The number of exophers increased as an adaptive response under proteostatic stress, e.g., in Alzheimer’s disease brain or in primary neurons from two tauopathy mouse models, where the exophers likely facilitated expulsion of proteotoxic material. Our findings suggest that exopherogenesis is a rare, innate house-keeping process that is elevated adaptively in response to proteostatic pressure and is a conserved mechanism from nematodes to humans.