Effects of glycosylation on the structure and function of the extracellular chaperone clusterin.

Citation data:

Biochemistry, ISSN: 0006-2960, Vol: 46, Issue: 5, Page: 1412-22

Publication Year:
2007
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Repository URL:
https://works.bepress.com/ja_aquilina/15; https://works.bepress.com/mark_wilson/27; https://ro.uow.edu.au/scipapers/3987
PMID:
17260971
DOI:
10.1021/bi062082v
Author(s):
Elise M. Stewart,‡; J. Andrew Aquilina,‡; Simon B. Easterbrook-Smith,§; Danielle Murphy-Durland,‖; Christian Jacobsen,⊥; Soren Moestrup,⊥ and; Mark R. Wilson*,‡
Publisher(s):
American Chemical Society (ACS); American Chemical Society
Tags:
Biochemistry, Genetics and Molecular Biology; Effects; glycosylation; structure; function; extracellular; chaperone; clusterin; CMMB; Life Sciences; Physical Sciences and Mathematics; Social and Behavioral Sciences
article description
Clusterin is the first well characterized, constitutively secreted extracellular chaperone that binds to exposed regions of hydrophobicity on non-native proteins. It may help control the folding state of extracellular proteins by targeting them for receptor-mediated endocytosis and intracellular lysosomal degradation. A notable feature of secreted clusterin is its heavy glycosylation. Although carbohydrate comprises approximately 20-25% of the total mass of the mature molecule, its function is unknown. Results from the current study demonstrate that deglycosylation of human serum clusterin had little effect on its overall secondary structure content but produced a small increase in solvent-exposed hydrophobicity and enhanced the propensity of the molecule to aggregate in solution. These changes were associated with increased binding to a variety of ligands but did not substantially impact the ability of clusterin to inhibit heat-induced precipitation of citrate synthase. Evidence suggesting that the normally conjugated sugars are important in the interaction of secreted clusterin with a lectin-type receptor on liver cells is also presented. Bulk expression of fully processed, glycosylated clusterin in mammalian cells is difficult, often producing inappropriately disulfide-bonded high molecular weight aggregates; this has hampered previous studies aimed at identifying those regions of the molecule important in its chaperone action. The current results suggest that it may be possible in the future to study the structure and chaperone function of clusterin using recombinant protein (lacking sugars) conveniently bulk-expressed in bacteria.