Litcius/Paper detail

The translocon-associated protein (TRAP) complex regulates quality control of N-linked glycosylation during ER stress

Chatchai Phoomak, Wei Cui, Thomas J. Hayman, Seok‐Ho Yu, Peng Zhao, Lance Wells, Richard Steet, Joseph N. Contessa

2021Science Advances51 citationsDOIOpen Access PDF

Abstract

Asparagine (N)-linked glycosylation is required for endoplasmic reticulum (ER) homeostasis, but how this co- and posttranslational modification is maintained during ER stress is unknown. Here, we introduce a fluorescence-based strategy to detect aberrant N-glycosylation in individual cells and identify a regulatory role for the heterotetrameric translocon-associated protein (TRAP) complex. Unexpectedly, cells with knockout of SSR3 or SSR4 subunits restore N-glycosylation over time concurrent with a diminished ER stress transcriptional signature. Activation of ER stress or silencing of the ER chaperone BiP exacerbates or rescues the glycosylation defects, respectively, indicating that SSR3 and SSR4 enable N-glycosylation during ER stress. Protein levels of the SSR3 subunit are ER stress and UBE2J1 dependent, revealing a mechanism that coordinates upstream N-glycosylation proficiency with downstream ER-associated degradation and proteostasis. The fidelity of N-glycosylation is not static in both nontransformed and tumor cells, and the TRAP complex regulates ER glycoprotein quality control under conditions of stress.

Topics & Concepts

Trap (plumbing)TransloconGlycosylationCell biologyUnfolded protein responseMechanism (biology)N-linked glycosylationStress (linguistics)ChemistryBiologyChromosomal translocationEndoplasmic reticulumBiochemistryGlycoproteinPhysicsLinguisticsQuantum mechanicsPhilosophyGeneMeteorologyGlycanGlycosylation and Glycoproteins ResearchGalectins and Cancer BiologyEndoplasmic Reticulum Stress and Disease