Project description:The intestinal anaerobic bacterium Akkermansia muciniphila is specialized in the degradation of mucins, which are heavily O-glycosylated proteins that constitute the major components of the mucus lining the intestine. Despite that adhesion to mucins is considered critical for the persistence of A. muciniphila in the human intestinal tract, our knowledge of how this intestinal symbiont recognizes and binds to mucins is still limited. Here, we first show that the mucin-binding properties of A. muciniphila are independent of environmental oxygen concentrations and not abolished by pasteurization. We then dissected the mucin-binding properties of pasteurized A. muciniphila by use of a recently developed cell-based mucin array that enables display of the tandem repeats of human mucins with distinct O-glycan patterns and structures. We found that A. muciniphila recognizes the unsialylated LacNAc (Galβ1-4GlcNAc1-R) disaccharide selectively on core2 and core3 O-glycans. This disaccharide epitope is abundantly found on human colonic mucins capped by sialic acids, and we demonstrated that endogenous A. muciniphila neuraminidase activity can uncover the epitope and promote binding. In summary, our study provides insights into the mucin-binding properties important for colonization of a key mucin-foraging bacterium.

Project description:In a healthy colon, the stratified mucus layer serves as a crucial innate immune barrier to protect the epithelium from microbes. Mucins are complex glycoproteins that serve as a nutrient source for resident microflora but can be exploited by pathogens. We aimed to understand how the intestinal pathogen, Clostridioides diffiicile, independently uses or manipulates mucus to its benefit. Using a 2-D primary human intestinal epithelial cell model to generate physiologic mucus, we assessed C. difficile-mucus interactions through growth assays, RNA-Seq, biophysical characterization of mucus, and contextualization of an established genome-scale metabolic network reconstruction (GENRE). We found that host-derived mucus promotes C. difficile growth both in vitro and in an infection model. RNA-Seq revealed significant upregulation of genes related to metabolism in response to mucus, including genes involved in sugar uptake, the Wood-Ljungdahl pathway, and the glycine cleavage system. In addition, we identified differential expression of genes related to sensing and transcriptional control. Analysis of mutants with deletions in highly upregulated genes reflected the complexity of C. difficile-mucus interactions, with potential interplay between sensing and growth. Mucus also stimulated biofilm formation in vitro, which may in turn alter viscoelastic properties of mucus. Context-specific metabolic modeling confirmed differential metabolism and predicted importance of enzymes related to serine and glycine catabolism with mucus. Subsequent growth experiments supported these findings, indicating mucus is an important source of serine. Our results better define responses of C. difficile to human gastrointestinal mucus and highlight a flexibility in metabolism that may influence pathogenesis.

Project description:Candida albicans is the most prevalent fungal pathogen of humans, causing a variety of diseases ranging from superficial mucosal infections to deep-seated systemic infections. Mucus, the gel that coats all wet epithelial surfaces, accommodates Candida albicans as part of the regular microbiome where C. albicans resides asymptomatically in healthy humans. Through a series of in vitro experiments combined with genome-wide transcriptional profiling, we show that mucin biopolymers, the main gel-forming constituents of mucus, induce a new oval-shaped morphology in C. albicans in which a range of genes related to adhesion, filamentation, and biofilm formation are down-regulated. We also show that corresponding phenotypes are suppressed, rendering Candida incapable of forming biofilms on a range of different synthetic surfaces and human epithelial cells. Our data suggests that mucins can manipulate Candida physiology and we hypothesize that they are key regulators for retaining Candida in the host-compatible, commensal state. 3 biological replicates grown in log phase in the presence and absence of mucin for 8 hours. Experiments were performed using RPMI 1640 (Gibco 31800-089) buffered with 165mM MOPS and supplemented with 0.2% NaHCO3 and 2% glucose with and without 0.5% mucin.

Project description:Symbiotic interactions between humans and our communities of resident gut microbes (microbiota) play many roles in health and disease. Some gut bacteria utilize mucus as a nutrient source and can under certain conditions damage the protective barrier it forms, increasing disease susceptibility. We investigated how Ruminococcus torques—a known mucin-degrader that remains poorly studied despite its implication in inflammatory bowel diseases (IBDs)— degrades mucin glycoproteins or their component O-linked glycans to understand its effects on the availability of mucin-derived nutrients for other bacteria. We found that R. torques utilizes both mucin glycoproteins and released oligosaccharides from gastric and colonic mucins, degrading these substrates with a panoply of mostly constitutively expressed, secreted enzymes. Investigation of mucin oligosaccharide degradation by R. torques revealed strong fucosidase, sialidase and b1,4-galactosidase activities. There was a lack of detectable sulfatase and weak β1,3-galactosidase degradation, resulting in accumulation of glycans containing these structures on mucin polypeptides. While the Gram-negative symbiont, Bacteroides thetaiotaomicron grows poorly on mucin glycoproteins, we demonstrate a clear ability of R. torques to liberate products from mucins, making them accessible to B. thetaiotaomicron. This work underscores the diversity of mucin-degrading mechanisms in different bacterial species and the probability that some species are contingent on others for the ability to more fully access mucin-derived nutrients. The ability of R. torques to directly degrade a variety of mucin and mucin glycan structures and unlock released glycans for other species suggests that it is a keystone mucin degrader, which may contribute to its association with IBD.

Project description:Host factors in the intestine, such as mucus secretion, play an important role in selecting for the colonization of bacteria that contribute to intestinal health. Here we characterized the capability of commensal species to cleave and transport mucin-associated monosaccharides and found that several members of the Clostridiales order can utilize intestinal mucins as an energy source. One such mucin utilizer, Peptostreptococcus russellii, reduces susceptibility to epithelial injury in mice. Several Peptostreptococcus species contain a gene cluster that enables the production of the tryptophan metabolite indoleacrylic acid (IA), which we show has a beneficial effect on intestinal epithelial barrier function and mitigates inflammatory responses. Furthermore, metagenomic analysis of human stool samples revealed that the genetic capability of microbes to utilize mucins and metabolize tryptophan was diminished in patients with inflammatory bowel disease. Our data suggest that stimulating the production of IA to promote anti-inflammatory responses could have therapeutic benefit.

Project description:We use high-throughput sequencing to profile the response of oral commensal pathogen Streptococcus mutans to mucins protein polymers (human MUC5B mucins) and soluble mucin glycans (human MUC5B glycans and porcine MUC5AC glycans). We find that mucins and their glycans alter the regulation of dozens of S. mutans genes, specifically downregulating competence-associated quorum sensing genes. The transcriptional responses induced by MUC5B mucins, MUC5B glycans, and MUC5AC glycans are highly correlated.

Project description:Mucus accumulation is a key feature of respiratory diseases such as cystic fibrosis (CF) and chronic obstructive pulmonary disease (COPD). This is associated with goblet cell metaplasia and mucin overexpression, which can be induced by the increased activity of neutrophil elastase. The aim of the study was to characterization of mucus and epithelial cell proteomics in a porcine pancreatic elastase (PPE) mouse model of COPD/CF. The major proteins detected in mucus plugs obtained from PPE-treated mice included mucins Muc5ac and Muc5b, mucus-related proteins Clca1, Fcgbp, and Bpifb1. These proteins were upregulated in bronchoalveolar lavage (BAL) fluid and epithelial cells in mice exposed to elastase. Similar changes were found in BAL fluid of COPD patients.

Project description:The dense O-glycosylation of mucins plays an important role in the defensive properties of the mucus hydrogel. Aberrant glycosylation is often correlated with inflammation and pathology such as COPD, cancer, and Crohn’s disease. The inherent complexity of glycans and the diversity in the O-core structure constitute fundamental challenges for the analysis of mucin-type O-glycans. Due to coexistence of multiple isomers, multidimensional workflows such as LC-MS are required. To separate the highly polar carbohydrates, porous graphitized carbon is often used as a stationary phase. However, LC-MS workflows are time-consuming and lack reproducibility. Here we present a rapid alternative for separating and identifying O-glycans released from mucins based on trapped ion mobility mass spectrometry. Compared to established LC-MS, the acquisition time is reduced from an hour to two minutes. To test the validity, the developed workflow was applied to sputum samples from cystic fibrosis patients to map O-glycosylation features associated with disease.

Project description:Dr. Clausen's laboratory is interested in the structure, biosynthesis and genetic regulation of glycoconjugates, with a major focus on mucins. This laboratory is studying the glycosylation and secretion process of mucins and biological functions involving mucins. This lab is also interested in receptor modulation mediated by glycosylation or through glycosphingolipids. We have a particular interest in understanding how mucin type O-glycosylation is regulated. Mucin type O-glycosylation is controlled by the ppGalNAc-transferase multigene family. An estimated 23 iso-forms belong to this family, so the specific involvement of each individual iso-form in any given organ seems complex to understand. An initial attempt to comprehend how this multigene family regulates mucin type O-glycosylation, is to get insight into which iso-forms are expressed in different organs and cell types. For this reason we have generated monoclonal antibodies towards 7 iso-forms, and the list of ppGalNAc-T iso-form specific monoclonals is currently growing. We have done some immuno histochemistry on lung using the available monoclonals, but are keen on assessing the number of ppGalNAc-T's expressed in lung as determined this Glyco-array. We have focused on lung because a number of ppGalNAc-T acceptor polypeptides, belonging to the mucin gene family, are expressed in this organ. An RNA sample pooled from two independent adult human healthy lung tissue samples was analyzed

Project description:We use high-throughput sequencing to profile the response of the opportunistic fungal pathogen Candida albicans to mucins and mucin-glycans from the mucosal niche. We find that C. albicans undergoes a genome-wide phenotypic shift in response to mucins and their attached glycans suppressing virulence-associated pathways.