TY - JOUR
T1 - A family of di-glutamate mucin-degrading enzymes that bridges glycan hydrolases and peptidases
AU - Narimatsu, Yoshiki
AU - Büll, Christian
AU - Taleb, Víctor
AU - Liao, Qinghua
AU - Compañón, Ismael
AU - Sánchez-Navarro, David
AU - Durbesson, Fabien
AU - Vincentelli, Renaud
AU - Hansen, Lars
AU - Corzana, Francisco
AU - Rovira, Carme
AU - Henrissat, Bernard
AU - Clausen, Henrik
AU - Joshi, Hiren J.
AU - Hurtado-Guerrero, Ramon
N1 - Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2024.
PY - 2024
Y1 - 2024
N2 - Microbes utilize polysaccharides to protect their surfaces and build biofilms, whereas metazoans employ large mucins densely decorated with O-glycans to protect surfaces and keep microbes at a distance. However, gut microbes in mucus also feed on host mucins, thus imposing a need for continuous renewal to maintain protection, clearance and mucus homeostasis. Glycopeptidases that can cleave mucins are known, but mucinases that specifically cleave mucins are not. Here we report the discovery of such microbial mucinases that cleave mucins with trimmed glycans, recognize dense clusters of O-glycans, and employ a structural fold and catalytic machinery reminiscent of glycan hydrolases and peptidases. These di-glutamate mucinases are also found in eukaryotes, and we propose that they are designed to clear mucins following scavenging of O-glycans to promote healthy gut–microbiome homeostasis. (Figure presented.)
AB - Microbes utilize polysaccharides to protect their surfaces and build biofilms, whereas metazoans employ large mucins densely decorated with O-glycans to protect surfaces and keep microbes at a distance. However, gut microbes in mucus also feed on host mucins, thus imposing a need for continuous renewal to maintain protection, clearance and mucus homeostasis. Glycopeptidases that can cleave mucins are known, but mucinases that specifically cleave mucins are not. Here we report the discovery of such microbial mucinases that cleave mucins with trimmed glycans, recognize dense clusters of O-glycans, and employ a structural fold and catalytic machinery reminiscent of glycan hydrolases and peptidases. These di-glutamate mucinases are also found in eukaryotes, and we propose that they are designed to clear mucins following scavenging of O-glycans to promote healthy gut–microbiome homeostasis. (Figure presented.)
U2 - 10.1038/s41929-024-01116-5
DO - 10.1038/s41929-024-01116-5
M3 - Journal article
AN - SCOPUS:85187289072
VL - 7
SP - 386
EP - 400
JO - Nature Catalysis
JF - Nature Catalysis
SN - 2520-1158
ER -