Your search keyword '"fucosylated HMO"' showing total 4 results

1. Fucosylated Human Milk Oligosaccharide Foraging within the Species Bifidobacterium pseudocatenulatum Is Driven by Glycosyl Hydrolase Content and Specificity.

Author

Shani, Guy, Hoeflinger, Jennifer L., Heiss, Britta E., Masarweh, Chad F., Larke, Jules A., Jensen, Nick M., Wickramasinghe, Saumya, Davis, Jasmine C., Goonatilleke, Elisha, El-Hawiet, Amr, Nguyen, Linh, Klassen, John S., Slupsky, Carolyn M., Lebrilla, Carlito B., and Mills, David A.

Subjects

*BREAST milk, *OLIGOSACCHARIDES, *BIFIDOBACTERIUM, *ENZYME specificity, *COMPETITION (Psychology), *HEALTH maintenance organizations, *INFANT formulas, *BLOOD group antigens

Abstract

Human milk enriches members of the genus Bifidobacterium in the infant gut. One species, Bifidobacterium pseudocatenulatum, is found in the gastrointestinal tracts of adults and breastfed infants. In this study, B. pseudocatenulatum strains were isolated and characterized to identify genetic adaptations to the breastfed infant gut. During growth on pooled human milk oligosaccharides (HMOs), we observed two distinct groups of B. pseudocatenulatum, isolates that readily consumed HMOs and those that did not, a difference driven by variable catabolism of fucosylated HMOs. A conserved gene cluster for fucosylated HMO utilization was identified in several sequenced B. pseudocatenulatum strains. One isolate, B. pseudocatenulatum MP80, which uniquely possessed GH95 and GH29 a-fucosidases, consumed the majority of fucosylated HMOs tested. Furthermore, B. pseudocatenulatum SC585, which possesses only a single GH95 a-fucosidase, lacked the ability to consume the complete repertoire of linkages within the fucosylated HMO pool. Analysis of the purified GH29 and GH95 fucosidase activities directly on HMOs revealed complementing enzyme specificities with the GH95 enzyme preferring 1-2 fucosyl linkages and the GH29 enzyme favoring 1-3 and 1-4 linkages. The HMO-binding specificities of the family 1 solute-binding protein component linked to the fucosylated HMO gene cluster in both SC585 and MP80 are similar, suggesting differential transport of fucosylated HMO is not a driving factor in each strain's distinct HMO consumption pattern. Taken together, these data indicate the presence or absence of specific a-fucosidases directs the strain-specific fucosylated HMO utilization pattern among bifidobacteria and likely influences competitive behavior for HMO foraging in situ. [ABSTRACT FROM AUTHOR]

Published

2022

2. Utilization Efficiency of Human Milk Oligosaccharides by Human-Associated Akkermansia Is Strain Dependent.

Author

Luna, Estefani, Parkar, Shanthi G., Kirmiz, Nina, Hartel, Stephanie, Hearn, Erik, Hossine, Marziiah, Kurdian, Arinnae, Mendoza, Claudia, Orr, Katherine, Padilla, Loren, Ramirez, Katherine, Salcedo, Priscilla, Serrano, Erik, Choudhury, Biswa, Paulchakrabarti, Mousumi, Parker, Craig T., Huynh, Steven, Cooper, Kerry, and Flores, Gilberto E.

Subjects

*BREAST milk, *OLIGOSACCHARIDES, *GLYCOSIDASES, *GALACTOSIDASES, *HEALTH maintenance organizations, *MICROBIAL ecology, *MUCINS

Abstract

Akkermansia muciniphila is a mucin-degrading bacterium found in the human gut and is often associated with positive human health. However, despite being detected by as early as 1 month of age, little is known about the role of Akkermansia in the infant gut. Human milk oligosaccharides (HMOs) are abundant components of human milk and are structurally similar to the oligosaccharides that comprise mucin, the preferred growth substrate of human-associated Akkermansia. A limited subset of intestinal bacteria has been shown to grow well on HMOs and mucin. We therefore examined the ability of genomically diverse strains of Akkermansia to grow on HMOs. First, we screened 85 genomes representing the four known Akkermansia phylogroups to examine their metabolic potential to degrade HMOs. Furthermore, we examined the ability of representative isolates to grow on individual HMOs in a mucin background and analyzed the resulting metabolites. All Akkermansia genomes were equipped with an array of glycoside hydrolases associated with HMO deconstruction. Representative strains were all able to grow on HMOs with various efficiencies and growth yields. Strain CSUN-19, belonging to the AmIV phylogroup, grew to the highest level in the presence of fucosylated and sialylated HMOs. This activity may be partially related to the increased copy numbers and/or the enzyme activities of the a-fucosidases, a-sialidases, and b-galactosidases. This study examines the utilization of individual purified HMOs by Akkermansia strains representing all known phylogroups. Further studies are required to examine how HMO ingestion influences gut microbial ecology in infants harboring different Akkermansia phylogroups. [ABSTRACT FROM AUTHOR]

Published

2022

3. Fucosylated Human Milk Oligosaccharide Foraging within the Species Bifidobacterium pseudocatenulatum Is Driven by Glycosyl Hydrolase Content and Specificity

Author

Chad F. Masarweh, Amr El-Hawiet, John S. Klassen, Carlito B. Lebrilla, David A. Mills, Carolyn M. Slupsky, Linh Nguyen, Nick M Jensen, Britta E. Heiss, Jennifer L Hoeflinger, Jasmine C.C. Davis, Jules A. Larke, Guy Shani, Elisha Goonatilleke, Saumya Wickramasinghe, and Dudley, Edward G

Subjects

Glycan, Hydrolases, Bifidobacterium pseudocatenulatum, substrate-binding protein, Oligosaccharides, Microbiology, Applied Microbiology and Biotechnology, fucosylated HMO, Hydrolase, Gene cluster, Humans, Fucosidase, Gene, health care economics and organizations, Nutrition, Pediatric, chemistry.chemical_classification, alpha-L-Fucosidase, fucosidases, Ecology, biology, Milk, Human, Catabolism, strain specificity, Infant, α-fucosidase, glycan metabolism, Oligosaccharide, alpha-fucosidase, Milk, chemistry, biology.protein, Food Microbiology, milk oligosaccharides, Female, Bifidobacterium, Human, Food Science, Biotechnology

Abstract

Human milk enriches members of the genus Bifidobacterium in the infant gut. One species, Bifidobacterium pseudocatenulatum, is found in the gastrointestinal tracts of adults and breastfed infants. In this study, B. pseudocatenulatum strains were isolated and characterized to identify genetic adaptations to the breastfed infant gut. During growth on pooled human milk oligosaccharides (HMOs), we observed two distinct groups of B. pseudocatenulatum, isolates that readily consumed HMOs and those that did not, a difference driven by variable catabolism of fucosylated HMOs. A conserved gene cluster for fucosylated HMO utilization was identified in several sequenced B. pseudocatenulatum strains. One isolate, B. pseudocatenulatum MP80, which uniquely possessed GH95 and GH29 α-fucosidases, consumed the majority of fucosylated HMOs tested. Furthermore, B. pseudocatenulatum SC585, which possesses only a single GH95 α-fucosidase, lacked the ability to consume the complete repertoire of linkages within the fucosylated HMO pool. Analysis of the purified GH29 and GH95 fucosidase activities directly on HMOs revealed complementing enzyme specificities with the GH95 enzyme preferring 1-2 fucosyl linkages and the GH29 enzyme favoring 1-3 and 1-4 linkages. The HMO-binding specificities of the family 1 solute-binding protein component linked to the fucosylated HMO gene cluster in both SC585 and MP80 are similar, suggesting differential transport of fucosylated HMO is not a driving factor in each strain's distinct HMO consumption pattern. Taken together, these data indicate the presence or absence of specific α-fucosidases directs the strain-specific fucosylated HMO utilization pattern among bifidobacteria and likely influences competitive behavior for HMO foraging in situ. IMPORTANCE Often isolated from the human gut, microbes from the bacterial family Bifidobacteriaceae commonly possess genes enabling carbohydrate utilization. Isolates from breastfed infants often grow on and possess genes for the catabolism of human milk oligosaccharides (HMOs), glycans found in human breast milk. However, catabolism of structurally diverse HMOs differs between bifidobacterial strains. This study identifies key gene differences between Bifidobacterium pseudocatenulatum isolates that may impact whether a microbe successfully colonizes an infant gut. In this case, the presence of complementary α-fucosidases may provide an advantage to microbes seeking residence in the infant gut. Such knowledge furthers our understanding of how diet drives bacterial colonization of the infant gut.

Published

2022

4. Utilization Efficiency of Human Milk Oligosaccharides by Human-Associated Akkermansia Is Strain Dependent

Author

Katherine Orr, Steven Huynh, Shanthi G. Parkar, Priscilla Salcedo, Nina Kirmiz, Arinnae Kurdian, Mousumi Paulchakrabarti, Marziiah Hossine, Erik Serrano, Katherine Ramirez, Claudia Mendoza, Stephanie Hartel, Estefani Luna, Kerry K. Cooper, Gilberto E. Flores, Erik Hearn, Craig T. Parker, Loren Padilla, and Biswa Choudhury

Subjects

GH29, HMO utilization, Oligosaccharides, Breast milk, Applied Microbiology and Biotechnology, Genome, Microbiology, Microbial Ecology, fucosylated HMO, Microbial ecology, Verrucomicrobia, Humans, sialylated HMO, health care economics and organizations, Ecology, biology, Milk, Human, Mucin, Infant, Akkermansia, biology.organism_classification, glycoside hydrolase (GH), Akkermansia phylogroups, Gastrointestinal Microbiome, GH95, Colostrum, human milk oligosaccharides, Female, Bacteria, Akkermansia muciniphila, Food Science, Biotechnology

Abstract

Akkermansia muciniphila is a mucin-degrading bacterium found in the human gut and is often associated with positive human health. However, despite being detected by as early as 1 month of age, little is known about the role of Akkermansia in the infant gut. Human milk oligosaccharides (HMOs) are abundant components of human milk and are structurally similar to the oligosaccharides that comprise mucin, the preferred growth substrate of human-associated Akkermansia. A limited subset of intestinal bacteria has been shown to grow well on HMOs and mucin. We therefore examined the ability of genomically diverse strains of Akkermansia to grow on HMOs. First, we screened 85 genomes representing the four known Akkermansia phylogroups to examine their metabolic potential to degrade HMOs. Furthermore, we examined the ability of representative isolates to grow on individual HMOs in a mucin background and analyzed the resulting metabolites. All Akkermansia genomes were equipped with an array of glycoside hydrolases associated with HMO deconstruction. Representative strains were all able to grow on HMOs with various efficiencies and growth yields. Strain CSUN-19, belonging to the AmIV phylogroup, grew to the highest level in the presence of fucosylated and sialylated HMOs. This activity may be partially related to the increased copy numbers and/or the enzyme activities of the α-fucosidases, α-sialidases, and β-galactosidases. This study examines the utilization of individual purified HMOs by Akkermansia strains representing all known phylogroups. Further studies are required to examine how HMO ingestion influences gut microbial ecology in infants harboring different Akkermansia phylogroups. IMPORTANCE Human milk oligosaccharides (HMOs) are the third most abundant component of breast milk and provide several benefits to developing infants, including the recruitment of beneficial bacteria to the human gut. Akkermansia strains are largely considered beneficial bacteria and have been detected in colostrum, breast milk, and young infants. A. muciniphila MucT, belonging to the AmI phylogroup, contributes to the HMO deconstruction capacity of the infant. Here, using phylogenomics, we examined the genomic capacities of four Akkermansia phylogroups to deconstruct HMOs. Indeed, each phylogroup contained differences in their genomic capacities to deconstruct HMOs, and representative strains of each phylogroup were able to grow using HMOs. These Akkermansia-HMO interactions potentially influence gut microbial ecology in early life, a critical time for the development of the gut microbiome and infant health.

Published

2022