Author: Benyair, Ron; Ogen-Shtern, Navit; Lederkremer, Gerardo Z
Title: Glycan regulation of ER-associated degradation through compartmentalization. Cord-id: ghv2al9u Document date: 2015_1_1
ID: ghv2al9u
Snippet: The internal environment of the eukaryotic cell is divided by membranes into various organelles, containing diverse functional subcompartments, which allow complex cellular life. The quality control of newly made secretory proteins relies on the ability of the endoplasmic reticulum (ER) to segregate and compartmentalize molecules at different folding states. These folding states are communicated by N-glycans present on most secretory proteins. In ER-associated degradation (ERAD), protein molecul
Document: The internal environment of the eukaryotic cell is divided by membranes into various organelles, containing diverse functional subcompartments, which allow complex cellular life. The quality control of newly made secretory proteins relies on the ability of the endoplasmic reticulum (ER) to segregate and compartmentalize molecules at different folding states. These folding states are communicated by N-glycans present on most secretory proteins. In ER-associated degradation (ERAD), protein molecules that have been identified as terminally misfolded are sent for degradation at the cytosolic proteasomes after being dislocated from the ER to the cytosol. This review will focus on how misfolded glycoprotein molecules are segregated from their properly folded counterparts and targeted to ERAD. The pathway involves compartmentalization, which is intimately linked to differential N-glycan processing. Recent data suggests that these processes are very dynamic, and include transient assembly of ERAD machinery complexes.
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