Quality control in the endoplasmic reticulum (ER) determines the fate of newly synthesized glycoproteins toward either correct folding or disposal by ER-associated degradation. Initiation of the disposal process involves selective trimming ofN-glycans attached to misfolded glycoproteins by ER α-mannosidase I and subsequent recognition by the ER degradation-enhancing α-mannosidase-like protein family of lectins, both members of glycosylhydrolase family 47. The unusual inverting hydrolytic mechanism catalyzed by members of this family is investigated here by a combination of kinetic and binding analyses of wild type and mutant forms of human ER α-mannosidase I as well as by structural analysis of a co-complex with an uncleaved thiodisaccharide substrate analog. These data reveal the roles of potential catalytic acid and base residues and the identification of a novel3S1sugar conformation for the bound substrate analog. The co-crystal structure described here, in combination with the1C4conformation of a previously identified co-complex with the glycone mimic, 1-deoxymannojirimycin, indicates that glycoside bond cleavage proceeds through a least motion conformational twist of a properly predisposed substrate in the –1 subsite. A novel3H4conformation is proposed as the exploded transition state.
Differences in endoplasmic-reticulum quality control determine the cellular response to disease-associated mutants of proteolipid protein
