J Cell Sci. 2022 Nov 03. pii: jcs.260294. [Epub ahead of print]
Phase separation of ER-exit-sites (ERES) components into membraneless compartments, the Sec bodies, occurs in Drosophila cells upon specific cellular stressors, i.e., salt stress and amino acid starvation, and their formation is linked to the early secretory pathway inhibition. Here, we show Sec bodies also form in secretory mammalian cells upon the same stress. These reversible and membraneless structures are positive for ERES components, including both Sec16A and Sec16B isoforms and COPII subunits. We find that Sec16A, but not Sec16B, is a driver for Sec body formation, and that the coalescence of ERES components into Sec bodies occurs by fusion. Lastly, we show that the stress-induced coalescence of ERES components into Sec bodies precedes ER-exit inhibition, leading to their progressive depletion from ERES that become non-functional. Stress-relief causes an immediate dissolution of Sec bodies and the concomitant restoration of ER-exit. We propose that the dynamic conversion between ERES and Sec body assembly, driven by Sec16A, regulates protein exit from the ER during stress and upon stress-relief in mammalian cells, thus providing a conserved pro-survival mechanism in response to stress.
Keywords: ER exit sites; ERES remodeling; Early secretory pathway; Mammalian cells; Phase separation; Protein transport; Sec body; Sec16; Stress