Abstract
The mucin 2 glycoprotein assembles into a complex hydrogel that protects intestinal epithelia and houses the gut microbiome. A major step in mucin 2 assembly is further multimerization of preformed mucin dimers, thought to produce a honeycomb-like arrangement upon hydrogel expansion. Important open questions are how multiple mucin 2 dimers become covalently linked to one another and how mucin 2 multimerization compares with analogous processes in related polymers such as respiratory tract mucins and the hemostasis protein von Willebrand factor. Here we report the x-ray crystal structure of the mucin 2 multimerization module, found to form a dimer linked by two intersubunit disulfide bonds. The dimer structure calls into question the current model for intestinal mucin assembly, which proposes disulfide-mediated trimerization of the same module. Key residues making interactions across the dimer interface are highly conserved in intestinal mucin orthologs, supporting the physiological relevance of the observed quaternary structure. With knowledge of the interface residues, it can be demonstrated that many of these amino acids are also present in other mucins and in von Willebrand factor, further indicating that the stable dimer arrangement reported herein is likely to be shared across this functionally broad protein family. The mucin 2 module structure thus reveals the manner by which both mucins and von Willebrand factor polymerize, drawing deep structural parallels between macromolecular assemblies critical to mucosal epithelia and the vasculature.
Highlights
Mucin glycoproteins are the main structural component of mucus and play a central role in protecting exposed epithelia from pathogens and mechanical damage [1,2]
To enable removal of flexible glycans, the same mucin 2 (MUC2) fragment was produced in cells grown in the presence of kifunensine, an inhibitor of high-mannose carbohydrate processing [21]
The epithelial cells of organs including the lung and intestines cover enormous surface areas of the body that, though located internally, are exposed to biological and physical threats originating in the outside world
Summary
Mucin glycoproteins are the main structural component of mucus and play a central role in protecting exposed epithelia from pathogens and mechanical damage [1,2]. The distinctive amino acid composition, extensive glycosylation, and higherorder assembly of mucins determine their physical and biological properties. The viscosity and porosity of mucus are likely to be affected by the density of junctions in the mucin network [3]. Mucin multimerization occurs in a series of steps in the secretory pathway. The mucin protomer contains amino- and carboxy-terminal oligomerizing regions separated by a central serine- and threonine-rich segment heavily modified by O-linked glycans (Fig. 1a). In the first step of quaternary structure assembly, mucins dimerize by covalent association of their carboxy-terminal regions [5].
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