Plant N-glycan breakdown by human gut Bacteroides

Abstract: The major nutrients available to the human colonic microbiota are complex glycans derived from the diet. To degrade this highly variable mix of sugar structures, gut microbes have acquired a huge array of different carbohydrate-active enzymes (CAZymes), predominantly glycoside hydrolases, many of which have specificities that can be exploited for a range of different applications. Plant N-glycans are prevalent on proteins produced by plants and thus components of the diet, but the breakdown of these complex mo… Show more

“…PNGaseF-II ( E. meningoseptica ) also has specificity towards N-glycans with either α1,3- and α1,6-fucose on the core GlcNAc, but has a strong preference for denatured protein [ 10 ]. B035DRAFT_03341 PNGase from gut commensal Bacteroides massiliensis is selective for N-glycans with α1,3-fucose, and BF0811 PNGase from Bacteroides fragilis has very similar activity to PNGaseF [ 11 ].…”

“…For instance, three GH92 enzymes from B. thetaiotaomicron that are in the same operon as the GH18 BT3987 act in sequence to remove the α1,2-, α1,3-, and the first α1,6-mannose to leave Man2 ( Figure 3 ) [ 12 ]. In terms of plant N-glycans, the human gut commensal B. massiliensis and the plant pathogen Xanthomonas campestris have both been shown to encode a GH92 with specificity towards the core α1,3-mannose in plant N-glycans, so it is able to accommodate the β1,2-xylose in its binding site [ 11 ]. A recent study of three GH38 enzymes and a GH125 enzyme from Bifidobacterium longum , whose genes are encoded in the same operon, shows overlapping activities towards the linkages in high-mannose N-glycans ( Figure 3 ) [ 29 ].…”

“…Hydrolysis of core α1,3-fucose decorations characteristic of plant and invertebrate N-glycans has also been observed in GH29 enzymes from the human gut commensal B. massiliensis and plant pathogen X. campestris [ 11 , 45 ]. These enzymes require the N-glycan to be significantly processed before acting, suggesting that there is a strict sequence of deconstruction by these organisms for this substrate.…”

“…These enzymes require the N-glycan to be significantly processed before acting, suggesting that there is a strict sequence of deconstruction by these organisms for this substrate. In terms of the plant complex N-glycan α1,4-linked antennary fucose, two GH29 enzymes were identified from B. massiliensis that can remove this decoration from the full plant N-glycan structure [ 11 ].…”

“…( C ) Useful glycan structures discussed in the review. ( D ) Examples of glycan structures adapted from [ 11 ] from a variety of organisms displaying nonclassical compositions [ 54–59 ].…”

N-glycan breakdown by bacterial CAZymes

“…PNGaseF-II ( E. meningoseptica ) also has specificity towards N-glycans with either α1,3- and α1,6-fucose on the core GlcNAc, but has a strong preference for denatured protein [ 10 ]. B035DRAFT_03341 PNGase from gut commensal Bacteroides massiliensis is selective for N-glycans with α1,3-fucose, and BF0811 PNGase from Bacteroides fragilis has very similar activity to PNGaseF [ 11 ].…”

“…For instance, three GH92 enzymes from B. thetaiotaomicron that are in the same operon as the GH18 BT3987 act in sequence to remove the α1,2-, α1,3-, and the first α1,6-mannose to leave Man2 ( Figure 3 ) [ 12 ]. In terms of plant N-glycans, the human gut commensal B. massiliensis and the plant pathogen Xanthomonas campestris have both been shown to encode a GH92 with specificity towards the core α1,3-mannose in plant N-glycans, so it is able to accommodate the β1,2-xylose in its binding site [ 11 ]. A recent study of three GH38 enzymes and a GH125 enzyme from Bifidobacterium longum , whose genes are encoded in the same operon, shows overlapping activities towards the linkages in high-mannose N-glycans ( Figure 3 ) [ 29 ].…”

“…Hydrolysis of core α1,3-fucose decorations characteristic of plant and invertebrate N-glycans has also been observed in GH29 enzymes from the human gut commensal B. massiliensis and plant pathogen X. campestris [ 11 , 45 ]. These enzymes require the N-glycan to be significantly processed before acting, suggesting that there is a strict sequence of deconstruction by these organisms for this substrate.…”

“…These enzymes require the N-glycan to be significantly processed before acting, suggesting that there is a strict sequence of deconstruction by these organisms for this substrate. In terms of the plant complex N-glycan α1,4-linked antennary fucose, two GH29 enzymes were identified from B. massiliensis that can remove this decoration from the full plant N-glycan structure [ 11 ].…”

“…( C ) Useful glycan structures discussed in the review. ( D ) Examples of glycan structures adapted from [ 11 ] from a variety of organisms displaying nonclassical compositions [ 54–59 ].…”

N-glycan breakdown by bacterial CAZymes