UBE2J2 sensitizes the ERAD ubiquitination cascade to changes in membrane lipid saturation

Crosstalk between proteins and lipids forms the basis of homeostatic mechanisms in the endoplasmic reticulum (ER). ER-associated protein degradation (ERAD), a branch of the ubiquitin-proteasome system, regulates ER membrane properties by degrading lipid metabolic enzymes on demand. However, the ERAD components responsible for sensing membrane properties, as well as the underlying the sensing mechanisms, remain largely unknown. Using reconstituted systems with purified ERAD components, we demonstrate that membrane composition modulates the ubiquitination cascade at multiple levels. Early in the cascade, we identify the membrane-anchored E2 UBE2J2 as a sensor for lipid packing. In loosely packed membranes, UBE2J2 is largely inactive as its interaction with the membrane impedes ubiquitin loading. Tighter lipid packing induces a conformational switch in UBE2J2, facilitating interaction with E1. The activity of UBE2J2 governs downstream ubiquitin transfer by the E3 ligases RNF145, MARCHF6, and RNF139, targeting both themselves and the cholesterol biosynthetic enzyme, squalene monooxygenase (SQLE). Additionally, RNF145 directly senses cholesterol levels, rather than lipid packing, resulting in altered oligomerization and activity. Together, these findings indicate that the ERAD machinery integrates multiple lipid signals and suggest that early signal integration by UBE2J2 amplifies lipid-responsive degradation of metabolic enzymes.