STABILITY, QUATERNARY STRUCTURE, AND FOLDING OF INTERNAL, EXTERNAL, AND CORE-GLYCOSYLATED INVERTASE FROM YEAST

KERN, G and SCHULKE, N and SCHMID, FX and JAENICKE, R (1992) STABILITY, QUATERNARY STRUCTURE, AND FOLDING OF INTERNAL, EXTERNAL, AND CORE-GLYCOSYLATED INVERTASE FROM YEAST. PROTEIN SCIENCE, 1 (1). pp. 120-131. ISSN 0961-8368,

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Abstract

The role of carbohydrate chains for the structure, function, stability, and folding of glycoproteins has been investigated using invertase as a model. The protein is encoded by several different genes, and its carbohydrate moiety is heterogeneous. Both properties complicate physicochemical comparisons. Here we used the temperature-sensitive sec18 secretion mutant of yeast with a single invertase gene (SUC2). This mutant produces the carbohydrate-free internal invertase, the core-glycosylated form, and, at the permissive temperature, the fully glycosylated external enzyme, all with identical protein moieties. The core-glycosylated enzyme resembles the nascent glycoprotein chain that folds in the endoplasmic reticulum. Therefore, it may be considered a model for the in vivo folding of glycoproteins. In addition, because of its uniform glycosylation, it can be used to investigate the state of association of native invertase. Glycosylation is found to stabilize the protein with respect to thermal denaturation and chaotropic solvent components; the stabilizing effect does not differ for the external and the core-glycosylated forms. Unlike the internal enzyme, the glycosylated forms are protected from aggregation. Native internal invertase is a dimer (115 kDa) whereas the core-glycosylated enzyme is a mixture of dimers, tetramers, and octamers. This implies that core-glycosylation is necessary for oligomerization to tetramers and octamers. Dimerization is required and sufficient to generate enzymatic activity; further association does not alter the specific activity of core-glycosylated invertase, suggesting that the active sites of invertase are not affected by the association of the dimeric units. Reconstitution of the glycosylated and nonglycosylated forms of the enzyme after preceding guanidine denaturation depends on protein concentration. The maximum yield (almost-equal-to 80%) is obtained at pH 6-8 and protein concentrations less-than-or-equal-to 4-mu-g/mL for the nonglycosylated and less-than-or-equal-to 40-mu-g/mL for the glycosylated forms of the enzyme. The lower stability of the internal enzyme is reflected by a narrower pH range of reactivation and enhanced aggregation. As indicated by the sigmoidal reactivation kinetics at low protein concentration both folding and association are rate-determining.

Item Type: Article
Uncontrolled Keywords: N-ACETYLGLUCOSAMINIDASE-H; SECRETORY PATHWAY; SUC2 GENE; GLYCOPROTEINS; OLIGOSACCHARIDES; TUNICAMYCIN; MECHANISM; CELL; ASSOCIATION; FOLDING; GLYCOSYLATION; INVERTASE; QUATERNARY STRUCTURE; STABILITY; YEAST
Depositing User: Dr. Gernot Deinzer
Last Modified: 19 Oct 2022 08:44
URI: https://pred.uni-regensburg.de/id/eprint/54734

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