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Difference between revisions of "Carbohydrate Binding Module Family 103"
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== Structural Features == | == Structural Features == | ||
− | The CBM103 of the ''B. fluxus'' SGBP (BfSGBP-B) displays a β-barrel fold with an additional β-strand pair and two short α-helices <cite>Tamura2021</cite> (Figure | + | The CBM103 of the ''B. fluxus'' SGBP (BfSGBP-B) displays a β-barrel fold with an additional β-strand pair and two short α-helices <cite>Tamura2021</cite> (Figure 1a). 3D crystal structures showed that reducing ends of laminarin- or MLG-derived oligosaccharides bind on the top face of the β-barrel, which provides a 'shallow binding canyon'. Therefore, CBM103 classifies as a [[Carbohydrate-binding_modules|type C CBM]]. Polar- and CH-π-interactions mediate binding to trioses derived from laminarin and MLG. Trp164, which interacts with the glucose residue at the third subsite (Figure 1b), and Trp165, Lys172 and Asp221, which interact with the reducing-end glucose at the terminal subsite, were essential for binding <cite>Tamura2021</cite>. Replacing the individual residues with alanine abolished binding in each case, as shown by affinity gel electrophoresis. |
− | [[File: | + | In the ''B. fluxus'' SGBP, the CBM103 follows an N-terminal ‘PKD’ domain (Figure 1a). |
+ | |||
+ | [[File:bfluxus_3.png|thumb|'''Figure 1.''' 3D crystal structure of the CBM103-containing SGBP of ''Bacteroides fluxus''. '''a''' The CBM103 (blue) is preceded by an N-terminal 'PKD' domain (light violet) <cite>Tamura2021</cite>. Mixed-linkage glucotriose (pink) binds on a platform of CBM103 (PDB ID [{{PDBlink}}7KV6 7KV6]). '''b''' Residues of the binding site interacting with mixed-linkage glucotriose <cite>Tamura2021</cite>. The terminal subsite (interaction subsite 1), which is interacting with the reducing-end glucose residue, is encircled.]] | ||
== Functionalities == | == Functionalities == | ||
− | The CBM103-containing SGBP of ''B. fluxus'' (BfSGBP-B) was suggested to support glycan recognition and recruitment to the bacterial cellular surface in the human intestinal tract <cite>Tamura2021</cite>. Similarly, in 555 representative bacterial metagenome assembled genomes retrieved from phytoplankton blooms of three respective years (2016, 2018 and 2020) in the North Sea, 43 CBM103-only sequences were identified, some of which might function as SGBPs <cite>Zuehlke2024</cite>. All detected CBM103-containing sequences (82) belonged to the phylum Bacteroidota and covered also 17 CBM103-[[Carbohydrate_Binding_Module_Family_102|CBM102]] combinations, 21 CBM103-[[GH16]]_3 combinations as well as one CBM103-[[Carbohydrate_Binding_Module_Family_6|CBM6]]-[[GH5]]_46 combination. In ''C. forsetii'', the CBM103 is attached to a [[GH16]]_3, which was suggested to increase catalysis <cite>Zuehlke2024</cite>. | + | The CBM103-containing SGBP of ''B. fluxus'' (BfSGBP-B) was suggested to support glycan recognition and recruitment to the bacterial cellular surface in the human intestinal tract <cite>Tamura2021</cite>. Similarly, in 555 representative bacterial metagenome assembled genomes retrieved from phytoplankton blooms of three respective years (2016, 2018 and 2020) in the North Sea, 43 CBM103-only sequences were identified, some of which might function as SGBPs <cite>Zuehlke2024</cite>. All detected CBM103-containing sequences (82) belonged to the phylum Bacteroidota and covered also 17 CBM103-[[Carbohydrate_Binding_Module_Family_102|CBM102]] combinations, 21 CBM103-[[GH16]]_3 combinations as well as one CBM103-[[Carbohydrate_Binding_Module_Family_6|CBM6]]-[[GH5]]_46 combination. In ''C. forsetii'', the CBM103 is attached to a [[GH16]]_3, which was suggested to increase enzyme concentration and thus catalysis <cite>Zuehlke2024</cite>. |
== Family Firsts == | == Family Firsts == |
Latest revision as of 01:31, 7 November 2024
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CAZy DB link | |
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Ligand specificities
The CBM103-containing surface glycan-binding protein (SGBP) of Bacteroides fluxus (BfSGBP-B), a strain from the human intestinal tract, binds laminarin (Laminaria digitata) and mixed-linkage β(1,3)/β(1,4)-glucans (MLG, from Barley) as well as MLG oligosaccharides [1, 2]. The protein binds laminarin and MLG with similar affinity (Ka 8.63 X 104 M-1 and Ka 8.56 X 104 M-1, respectively) [1]. Binding of laminarin-derived oligosaccharides required a degree of polymerization (DP) of more than two and affinities ranged from Kd 3.63-7.61 x 10-5 M (for DP 3-6) [2]. DP3 and DP4 derived from MLG bound with similar affinities (Kd 1.23 x 10-5 M or 1.16 x 10-5 M, respectively), but a β(1,3)-glucosyl linkage at the reducing end was essential for binding.
Similarly, a dissected CBM103 of a multimodular laminarinase (GH16_3) from the marine flavobacterium Christiangramia forsetii KT0803T bound laminarin (Laminaria digitata) and MLG (from Icelandic moss, lichenan) as confirmed by affinity gel electrophoresis [3].
Structural Features
The CBM103 of the B. fluxus SGBP (BfSGBP-B) displays a β-barrel fold with an additional β-strand pair and two short α-helices [2] (Figure 1a). 3D crystal structures showed that reducing ends of laminarin- or MLG-derived oligosaccharides bind on the top face of the β-barrel, which provides a 'shallow binding canyon'. Therefore, CBM103 classifies as a type C CBM. Polar- and CH-π-interactions mediate binding to trioses derived from laminarin and MLG. Trp164, which interacts with the glucose residue at the third subsite (Figure 1b), and Trp165, Lys172 and Asp221, which interact with the reducing-end glucose at the terminal subsite, were essential for binding [2]. Replacing the individual residues with alanine abolished binding in each case, as shown by affinity gel electrophoresis.
In the B. fluxus SGBP, the CBM103 follows an N-terminal ‘PKD’ domain (Figure 1a).
Functionalities
The CBM103-containing SGBP of B. fluxus (BfSGBP-B) was suggested to support glycan recognition and recruitment to the bacterial cellular surface in the human intestinal tract [2]. Similarly, in 555 representative bacterial metagenome assembled genomes retrieved from phytoplankton blooms of three respective years (2016, 2018 and 2020) in the North Sea, 43 CBM103-only sequences were identified, some of which might function as SGBPs [3]. All detected CBM103-containing sequences (82) belonged to the phylum Bacteroidota and covered also 17 CBM103-CBM102 combinations, 21 CBM103-GH16_3 combinations as well as one CBM103-CBM6-GH5_46 combination. In C. forsetii, the CBM103 is attached to a GH16_3, which was suggested to increase enzyme concentration and thus catalysis [3].
Family Firsts
- First Identified
- CBM103 was first identified in an SGBP of B. fluxus (BfSGBP-B) [2], although binding of the SGBP to β-glucans was shown before [1]. Later, a CBM103-containing GH16_3 of C. forsetii led to the creation of the CBM family 103 [3].
- First Structural Characterization
- The CBM103-containing SGBP of B. fluxus represents the first 3D crystal structure, with and without ligands (PDB ID 7KV5 without ligand, PDB ID 7KV6 with DP3 from MLG, PDB ID 7KV7 with DP3 from laminarin) [2].
References
- Déjean G, Tamura K, Cabrera A, Jain N, Pudlo NA, Pereira G, Viborg AH, Van Petegem F, Martens EC, and Brumer H. (2020). Synergy between Cell Surface Glycosidases and Glycan-Binding Proteins Dictates the Utilization of Specific Beta(1,3)-Glucans by Human Gut Bacteroides. mBio. 2020;11(2). DOI:10.1128/mBio.00095-20 |
- Tamura K, Dejean G, Van Petegem F, and Brumer H. (2021). Distinct protein architectures mediate species-specific beta-glucan binding and metabolism in the human gut microbiota. J Biol Chem. 2021;296:100415. DOI:10.1016/j.jbc.2021.100415 |
- Zühlke MK, Ficko-Blean E, Bartosik D, Terrapon N, Jeudy A, Jam M, Wang F, Welsch N, Dürwald A, Martin LT, Larocque R, Jouanneau D, Eisenack T, Thomas F, Trautwein-Schult A, Teeling H, Becher D, Schweder T, and Czjzek M. (2024). Unveiling the role of novel carbohydrate-binding modules in laminarin interaction of multimodular proteins from marine Bacteroidota during phytoplankton blooms. Environ Microbiol. 2024;26(5):e16624. DOI:10.1111/1462-2920.16624 |