The immune‐mediated foreign body response to biomaterial implants can trigger the formation of insulating fibrotic capsules that can compromise implant function. To address this challenge, the intrinsic bioactivity of the mucin biopolymer, a heavily glycosylated protein that forms the protective mucus gel covering mucosal epithelia, is leveraged. By using a bioorthogonal inverse electron demand Diels–Alder reaction, mucins are crosslinked into implantable hydrogels. It is shown that mucin hydrogels (Muc‐gels) modulate the immune response driving biomaterial‐induced fibrosis. Muc‐gels do not elicit fibrosis 21 days after implantation in the peritoneal cavity of C57Bl/6 mice, whereas medical‐grade alginate hydrogels are covered by fibrous tissues. Further, Muc‐gels dampen the recruitment of innate and adaptive immune cells to the gel and trigger a pattern of very mild activation marked by a noticeably low expression of the fibrosis‐stimulating transforming growth factor beta 1 cytokine. Macrophages recruited to Muc‐gels upregulate the gene expression of the protein inhibitor of activated STAT 1 (PIAS1) and SH2‐containing phosphatase 1 (SHP‐1) cytokine regulatory proteins, which likely contributes to their low cytokine expression profiles. With this advance in mucin materials, an essential tool is provided to better understand mucin bioactivities and to initiate the development of new mucin‐based and mucin‐inspired “immune‐informed” materials for implantable devices subject to fibrotic encapsulation.
Commercial mucin glycoproteins are routinely used as a model to investigate the broad range of important functions mucins fulfill in our bodies, including lubrication, protection against hostile germs, and the accommodation of a healthy microbiome. Moreover, purified mucins are increasingly selected as building blocks for multifunctional materials, i.e., as components of hydrogels or coatings. By performing a detailed side-by-side comparison of commercially available and lab-purified variants of porcine gastric mucins, we decipher key molecular motifs that are crucial for mucin functionality. As two main structural features, we identify the hydrophobic termini and the hydrophilic glycosylation pattern of the mucin glycoprotein; moreover, we describe how alterations in those structural motifs affect the different properties of mucinson both microscopic and macroscopic levels. This study provides a detailed understanding of how distinct functionalities of gastric mucins are established, and it highlights the need for high-quality mucinsfor both basic research and the development of mucin-based medical products.
Proton transfer is integral to many biochemical processes. However, the direct observation and structural characterization of biological proton transfer has hitherto not been possible. Here, neutron crystallography directly locates two protons before and after a pH-induced two-proton transfer between the catalytic aspartic acid residues and the hydroxyl group of the bound clinical drug, darunavir, in the catalytic site of enzyme HIV-1 protease. The two-proton transfer is triggered by electrostatic effects arising from protonation state changes of surface residues far from the active site. The mechanism and pH effect are supported by QM/MM calculations. We propose that the low-pH proton configuration in the catalytic site is critical for the catalytic action of this enzyme and may apply more generally to other aspartic proteases. Neutrons therefore represent a superb probe to obtain structural details for proton transfer reactions in biological systems at a truly atomic level.
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