The role of the ER glucosyltransferase in the quality control of glycoprotein maturation

Pearse, Bradley R

01 January 2009

N-linked glycans serve as quality control tags in the eukaryotic secretory pathway. The endoplasmic reticulum (ER) protein UDP-glucose: glycoprotein glucosyltransferase 1 (GT1) is the main enzyme that modifies carbohydrate tags based upon the folding state of the maturing substrate. GT1 adds glucoses to non-glucosylated proteins that fail the quality control test, supporting ER retention through persistent binding to the lectin chaperones calnexin and calreticulin. How GT1 functions in its native environment on a maturing substrate as well as its ability to differentiate between native or aberrant secretory cargo is poorly understood. Additionally, due to inherent difficulties in studying GT1 activity in the cell, identification of endogenous substrates and the necessity of reglucosylation remain unknown. Here, we analyzed the role of GT1 in glycoprotein maturation in the intact mammalian ER. GT1 post-translationally reglucosylates N-linked glycans in slow-folding regions of substrate glycoproteins. Maturation mutants that disrupt oxidation or oligomerization also support regio-specific reglucosylation by GT1. Our studies have also revealed an abundant endogenous substrate of GT1, identified as prosaposin. GT1 is critical for the maturation of endogenous prosaposin. In the absence of GT1, the endogenous protein is mislocalized to large intracellular juxtanuclear aggregates. Together, these results propose that GT1 acts as an ER quality control sensor by post-translationally targeting glycans on slow folding or non-native domains to recruit chaperones specifically to critical unstable regions. GT1 plays a vital role in endogenous protein folding and trafficking, since in its absence misfolded proteins accumulate intracellularly. This investigation provides new insight into the integral role of GT1 in glycoprotein maturation.

Cellular biology|Biochemistry|Biophysics

Structure, function, and pharmacological chaperoning of human α-N-acetylgalactosaminidase

Clark, Nathaniel E

01 January 2012

Human lysosomal α-N-acetylgalactosaminidase (α-NAGAL) is responsible for the break down of glycolipids and glycopeptides that contain a terminal α-linked N-acetylgalactosamine residues. Deficiency of α-NAGAL results in Schindler and Kanzaki diseases. α-NAGAL is closely related to another lysosomal enzyme, α-galactosidase (α-GAL), which breaks down glycolipids and glycopeptides with a terminal α-linked galactose residues. Fabry disease results from a deficiency of α-galactosidase activity. We studied the reaction mechanism of both enzymes using biochemistry and X-ray crystallography, and found that α-GAL and α-NAGAL use an identical reaction mechanism, and differ only in substrate specificity. We solved the first structure of human α-NAGAL, allowing us to examine the disease-causing patient mutations in the context of a high-resolution 3D atomic structure, moving Schindler and Kanzaki disease into the realm of personalized molecular medicine. We then developed the first ever proof-of-principle treatment of Schindler and Kanzaki disease, by developing and characterizing 2 pharmacological chaperones that show promise to treat Schindler and Kanzaki diseases, which currently have no treatment options.

Cellular biology|Biochemistry|Biophysics