Expression and characterization of a novel recombinant version of the secreted human mucin MUC5AC in airway cell lines.

Molecular manipulation and expression of mucins, large glycoproteins that provide the structural framework of mucus, are challenging due to mucins' size and numerous domains, including variable number tandem repeat (VNTRs) regions that are sites of O-glycosylation. Only individual human mucin domains have been expressed in mammalian cells. We produced recombinant versions of MUC5AC, a major secreted mucin in the respiratory tract, encoding the N-terminus, C-terminus, N- and C-termini together, and N- and C-termini interspersed with two native tandem repeat sequences (N+2TR+C) in both tracheal and bronchial cell lines. The latter protein contains all of the functional domains required for the biosynthesis and secretion of glycosylated mucin. The N-terminus protein was found in monomeric and higher molecular mass forms suggesting that secreted MUC5AC may form a branched netlike structure analogous to that described for MUC2. At the C-terminus, proteins underwent cleavage, polymerization, and glycosylation. Thus, they appear to undergo pivotal processing steps as predicted for native MUC5AC, which is analogous to that for other individual recombinant mucin domains. Secretion occurred when cells were grown on transwell filter inserts but not on plastic, indicating that the extracellular environment likely plays a role in mucin processing. The secreted N+2TR+C protein differed in molecular mass from the intracellular form, indicating that additional processing occurred. These recombinant proteins, expressed in different backgrounds, can potentially address the role of different mucin domains on MUC5AC processing and function as well as the role of MUC5AC in health and disease.

Helicobacter pylori lipopolysaccharide interacts with TFF1 in a pH-dependent manner.

BACKGROUND & AIMS: Little is known about how bacteria establish chronic infections of mucosal surfaces. Helicobacter pylori (H. pylori), a chronic pathogen that lives in the gastric mucosa of humans, interacts with the trefoil factor family (TFF) protein TFF1, which is found in gastric mucus. We aimed to characterize the interaction of H. pylori with TFF1 and to assess the role of this interaction in mediating colonization. METHODS: Subcellular fractions of H. pylori were immobilized and then probed with TFF1, TFF2, or TFF3. The effect of glycosidases and preincubation with monosaccharides on the interaction and binding of TFF1 to a H. pylori adhesin was assessed. The interaction between H. pylori adhesin and TFF1 was characterized using surface plasmon resonance, flow cytometry, nondenaturing polyacrylamide gel electrophoresis, coimmunofluoresence, and incubation with tissue sections. RESULTS: The H. pylori core oligosaccharide portion (rough form) of lipopolysaccharide (RF-LPS) bound to TFF1 and to a lesser extent TFF3; this interaction was inhibited by incubation of RF-LPS with mannosidase, glucosidase, or mixed monosaccharides. TFF1 also bound to human serum albumin-conjugated mannose and glucose. The optimum pH for binding was 5.0-6.0 for TFF1 and 7.0 for TFF3. H. pylori bound TFF1 in gastric mucus ex vivo; binding of LPS-coated latex beads to human antral gastric tissue was inhibited by TFF1. CONCLUSIONS: TFF1 interacts specifically with H. pylori RF-LPS. The pH dependence of this interaction indicates that binding of H. pylori to TFF1 in the stomach could promote colonization of the mucus layer adjacent to the gastric epithelial surface.