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Difference between revisions of "Glycoside Hydrolase Family 186"

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* [[Author]]: [[User:Sei Motouchi|Sei Motouchi]]
 
* [[Author]]: [[User:Sei Motouchi|Sei Motouchi]]
 
* [[Responsible Curator]]:  [[User:Masahiro Nakajima|Masahiro Nakajima]]
 
* [[Responsible Curator]]:  [[User:Masahiro Nakajima|Masahiro Nakajima]]
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== Substrate specificities ==
 
== Substrate specificities ==
The defining member of GH186, a β-1,2-glucanase from ''Escherichia coli'' (EcOpgD) was identified, characterized and structurally analyzed as reported in 2023<cite>Motouchi2023</cite>. Subsequently GH186 homolog from ''Xanthomonas campestris'' pv. ''campestris'' (XccOpgD) was found to be anomer-inverting transglycoslyase which specifically substitute β-1,2-glucosidic bond of β-1,2-glucan to α-1,6-glucosidic bond<cite>Motouchi2024</cite>. EcOpgD and XccOpgD are specific toward β-1,2-glucan and the amino acid residues for recognizing β-1,2-glucan at common subsites between EcOpgD and XccOpgD (subsite –7 to +6) are highly conserved in GH186<cite>Motouchi2023 Motouchi2024</cite>. However, the reaction types of EcOpgD and XccOpgD are different from each other<cite>Motouchi2023 Motouchi2024</cite>. EcOpgD is a β-1,2-glucanase and preferentially generate β-1,2-glucooligosaccharides (Sopns, n is degree of polymerization, DP) with DPs of 6 and 7 from linear β-1,2-glucan<cite>Motouchi2023</cite>. Final products produced by EcOpgD are Sop6–10, indicating that EcOgpD hydrolyzes Sopns with DPs of 11 and higher<cite>Motouchi2023</cite>. XccOpgD generates only α-1,6-cyclized β-1,2-glucohexadecaose from linear β-1,2-glucan<cite>Motouchi2024</cite>. Almost all family members are found in Pseudomonadota, especially in gamma proteobacteria.  
+
The defining member of GH186, a β-1,2-glucanase from ''Escherichia coli'' (EcOpgD) was identified, characterized and structurally analyzed as reported in 2023 <cite>Motouchi2023</cite>. Subsequently, GH186 homolog from ''Xanthomonas campestris'' pv. ''campestris'' (XccOpgD) was found to be an anomer-[[inverting]] [[Transglycosylases|transglycosylase]] which specifically generated α-1,6-glucosidic bonds from β-1,2-glucan donors <cite>Motouchi2024</cite>. EcOpgD and XccOpgD are specific toward β-1,2-glucan and the amino acid residues for recognizing β-1,2-glucan at common subsites between EcOpgD and XccOpgD (subsite –7 to +6) are highly conserved in GH186 <cite>Motouchi2023 Motouchi2024</cite>. However, the reaction types of EcOpgD and XccOpgD are different from each other <cite>Motouchi2023 Motouchi2024</cite>. EcOpgD is a β-1,2-glucanase that preferentially generates β-1,2-glucooligosaccharides (Sop''n''s, where ''n'' indicates a degree of polymerization, DP) with DPs of 6 and 7 from linear β-1,2-glucan <cite>Motouchi2023</cite>. Final products produced by EcOpgD are Sop6–10, indicating that EcOgpD hydrolyzes Sopns with DPs of 11 and higher <cite>Motouchi2023</cite>. XccOpgD generates only α-1,6-cyclized β-1,2-glucohexadecaose from linear β-1,2-glucan <cite>Motouchi2024</cite>. Almost all family members are found in Pseudomonadota, particularly gamma proteobacteria.
 +
 
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
[[File:EcOgpD.png|thumb|'''Figure 1. Catalytic center of EcOpgD''']][[File:XccOpgD.png|thumb|'''Figure 2. Catalytic center of XccOpgD''']]Optical rotation and NMR analyses indicate that EcOpgD and XccOpgD adopt anomer-inverting mechanism<cite>Motouchi2023 Motouchi2024</cite>. X-ray structural analysis and mutational analysis suggest that D388 in EcOpgD and the equivalent residue in XccOpgD, D379, directly protonate the scissile glycosidic bond as general acids ('''Figure 1, 2''')<cite>Motouchi2023 Motouchi2024</cite>. These analyses also suggest that D300 in EcOpgD and the equivalent residue in XccOpgD, D291, activate the nucleophile via 4-hydroxy group of the Glc moiety at subsite –1 and two water molecules as general bases<cite>Motouchi2023 Motouchi2024</cite>. Interestingly, nucleophiles of EcOpgD and XccOpgD are different from each other<cite>Motouchi2023 Motouchi2024</cite>. The nucleophiles of EcOpgD and XccOpgD are a water molecule and the 6-hydroxy group of Glc moiety at subsite –16, respectively<cite>Motouchi2023 Motouchi2024</cite>. The difference in nucleophile among GH186 family is probably due to how a nucleophile and a following Grotthuss proton relay route are stabilized by residues and/or ligands.
+
[[File:EcOgpD.png|thumb|300px|right|'''Figure 1. Catalytic center of EcOpgD''']][[File:XccOpgD.png|thumb|300px|right|'''Figure 2. Catalytic center of XccOpgD''']]Optical rotation and NMR analyses indicated that EcOpgD and XccOpgD use anomer-[[inverting]] mechanisms <cite>Motouchi2023 Motouchi2024</cite>. X-ray structural analysis (see below) and mutational analysis suggest that D388 in EcOpgD and the equivalent residue in XccOpgD, D379, directly protonate the scissile glycosidic bond as general acids ('''Figure 1, 2''') <cite>Motouchi2023 Motouchi2024</cite>. These analyses also suggested that D300 in EcOpgD and the equivalent residue in XccOpgD, D291, act as as general bases to activate the nucleophile via a chain comprising the 4-hydroxy group of the Glc moiety at subsite –1 and two water molecules <cite>Motouchi2023 Motouchi2024</cite>. In EcOpgD (glucanase), the nucleophile is a water molecule and in XccOpgD ([[Transglycosylases|transglycosylase]]) the nucleophile is the 6-hydroxy group of the terminal Glc moiety at position –16 in the chain <cite>Motouchi2023 Motouchi2024</cite>. It should be noted that [[Transglycosylases|transglycosylation]] is more typical of anomer-[[retaining]] GHs, which use a covalent glycosyl-enzyme intermediate, further highlighting the uniqueness of these GH186 members.
 +
 
 +
The difference in nucleophiles among GH186 family is probably due to how the nucleophile and the Grotthuss proton relay are stabilized. While W441, which is important for stabilizing nucleophilic water in EcOpgD, is not conserved in GH186, W76, which is important for stacking with the acceptor Glc moiety in XccOpgD is broadly conserved (but not in the clade of EcOpgD) ('''Figure 2''') <cite>Motouchi2023 Motouchi2024</cite>. Therefore, GH186 seems to be fundamentally an anomer-[[inverting]] [[Transglycosylases|transglycosylase]] family. In addition, the Grotthuss proton relay is sequestered (stabilized) not by amino acid sequence but by positioning of the acceptor substrate in XccOpgD, with the result that a water molecule is not suitable as a nucleophile for efficient Grotthuss proton relay. This explains why XccOpgD is a specific [[Transglycosylases|transglycosylase]] <cite>Motouchi2024</cite>.
  
Particularly, while W441 important for stabilizing nucleophilic water in EcOpgD is not conserved in GH186, W76 important for stacking acceptor Glc moiety in XccOpgD is broadly conserved in GH186 (but not in the clade of EcOpgD) ('''Figure 2''')<cite>Motouchi2023 Motouchi2024</cite>. Therefore, GH186 seems to be fundamentally an anomer-inverting transglycosylase family. In addition, the Grotthuss proton relay pathway is sequestered (stabilized) not by amino acid sequence but by acceptor substrate moiety in XccOpgD, resulting that a water molecule is not suitable as a nucleophile for efficient Grotthuss proton relay. This is the reason why XccOpgD is specific to transglycosylation<cite>Motouchi2024</cite>.
 
 
== Catalytic Residues ==
 
== Catalytic Residues ==
General acid and base of EcOpgD are D388 and D300, respectively, and the catalytic residues of XccOpgD are also equivalent to that of EcOpgD (D379 and D291, respectively)<cite>Motouchi2023 Motouchi2024</cite>.
+
As described above, the identities of the catalytic residues were indicated by X-ray crystallography and supported by site-directed mutagenesis.  The general acid and general base of EcOpgD are D388 and D300, respectively, and the equivalent catalytic residues of XccOpgD are D379 and D291, respectively) <cite>Motouchi2023 Motouchi2024</cite>.
 +
 
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
The ligand-free structure of OpgG from ''E. coli'' (EcOpgG) was determined at 2.4 Å (PDB: 1txk)<cite>Hanoulle2004</cite>. The ligand-free structure of EcOpgD was determined at 2.95 Å (PDB: 8IOX)<cite>Motouchi2023</cite>. Michaelis complexes of EcOpgD (D388N, co-crystal), EcOpgG (D361N, soaking) and XccOpgD (D379N, soaking) with β-1,2-glucan were determined at 2.06, 1.81, 2.25 Å, respectively (PDB: 8IP1, 8IP2, 8X18)<cite>Motouchi2023 Motouchi2024</cite>.
+
The ligand-free structure of OpgG from ''E. coli'' (EcOpgG) was determined at 2.4 Å resolution ([{{PDBlink}}1TXK PDB 1TXK]) <cite>Hanoulle2004</cite>. The ligand-free structure of EcOpgD was determined at 2.95 Å resolution ([{{PDBlink}}8IOX PDB 8IOX]) <cite>Motouchi2023</cite>. Michaelis complexes of EcOpgD (D388N, co-crystal), EcOpgG (D361N, soaking) and XccOpgD (D379N, soaking) with β-1,2-glucan were determined at 2.06, 1.81, and 2.25 Å resolutions, respectively ([{{PDBlink}}8IP1 PDB 8IP1], [{{PDBlink}}8IP2 PDB 8IP2], [{{PDBlink}}8X18 PDB 8X18]) <cite>Motouchi2023 Motouchi2024</cite>.  Notably, GH186 is strucuturally unique, i.e. lacks 3-D structural homologs, among all of the GHs families known at the time <cite>Motouchi2023</cite>.
  [[File:The overall structure of Michaelis complex of EcOpgG (monomer).jpg|thumb|'''Figure 3. The overall Michaelis complex structure of EcOpgG (monomer)''']]There is no structural homolog of GH186 in the whole GH families<cite>Motouchi2023</cite> (January 2024).
+
  [[File:The overall structure of Michaelis complex of EcOpgG (monomer).jpg|thumb|400px|right|'''Figure 3. The overall Michaelis complex structure of EcOpgG (monomer)''']]
 +
 
 +
EcOpgG consists of an N-terminal domain (residues 22–388, β-sandwich) and a C-terminal domain (residues 401–511, Ig-like fold) ('''Figure 3'''). The two domains are connected with one turn of a 3<sub>10</sub> helix <cite>Hanoulle2004 Motouchi2023</cite>. The loop region (residues 409-425, Loop A below) in the C-terminal domain of the ligand-free structure organizes into β-strands in the Michaelis complex structure. In the Michaelis complex, the β-strands extend toward the catalytic center of another chain in the dimer to cover the proton transfer pathway from a nucleophile to the general base catalyst <cite>Motouchi2023</cite>. However, the sequence of Loop A is diversified in GH186 family. Indeed, Loop A in EcOpgD sequesters the proton transfer pathway from the solvent, while that of EcOpgG does not completely, which is consistent with the drastically reduced hydrolytic activity of EcOpgG compared with EcOpgD <cite>Motouchi2023</cite>. In addition, the corresponding Loop A of XccOpgD is too short to reach the catalytic center, which makes space to accommodate a β-1,2-glucooligosaccharide acceptor <cite>Motouchi2024</cite>.
  
EcOpgG consists of an N-terminal domain (residues 22–388, β-sandwich) and a C-terminal domain (residues 401–511, Ig-like fold) ('''Figure 3'''). The two domains are connected with one turn of 3<sub>10</sub> helix<cite>Hanoulle2004 Motouchi2023</cite>. The loop region (residues 409-425, Loop A below) in the C-terminal domain of the ligand-free structure changes into β-strands in the Michaelis complex structure. In the Michaelis complex, the β-strands reach for the catalytic center of another chain in the dimer to cover the proton transfer pathway from a nucleophile to the general base catalyst<cite>Motouchi2023</cite>. However, the sequence of Loop A is diversified in GH186 family. Indeed, Loop A in EcOpgD sequesters the proton transfer pathway from the solvent, while that of EcOpgG does not completely, which is consistent with the drastically reduced hydrolytic activity of EcOpgG compared with EcOpgD<cite>Motouchi2023</cite>. In addition, the Loop A of XccOpgD is too short to reach the catalytic center, making the space for recognizing an acceptor β-1,2-glucooligosaccharide moiety<cite>Motouchi2024</cite>.
 
 
== Family Firsts ==
 
== Family Firsts ==
;First stereochemistry determination: EcOpgD by optical rotation<cite>Motouchi2023</cite>.
+
;First stereochemistry determination: EcOpgD by optical rotation <cite>Motouchi2023</cite>.
;First general acid residue identification: EcOpgD by X-ray crystallography and site-directed mutagenesis<cite>Motouchi2023</cite>.
+
;First general acid residue identification: EcOpgD by X-ray crystallography and site-directed mutagenesis <cite>Motouchi2023</cite>.
;First general base residue identification: EcOpgD by X-ray crystallography and site-directed mutagenesis<cite>Motouchi2023</cite>.
+
;First general base residue identification: EcOpgD by X-ray crystallography and site-directed mutagenesis <cite>Motouchi2023</cite>.
;First 3-D structure: EcOpgG by X-ray crystallography<cite>Hanoulle2004</cite>.
+
;First 3-D structure: EcOpgG by X-ray crystallography <cite>Hanoulle2004</cite>.
 
== References ==
 
== References ==
 
<biblio>
 
<biblio>

Latest revision as of 15:39, 18 July 2024

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Glycoside Hydrolase Family GH186
Clan None
Mechanism Inverting
Active site residues Asp
CAZy DB link
https://www.cazy.org/GH186.html


Substrate specificities

The defining member of GH186, a β-1,2-glucanase from Escherichia coli (EcOpgD) was identified, characterized and structurally analyzed as reported in 2023 [1]. Subsequently, GH186 homolog from Xanthomonas campestris pv. campestris (XccOpgD) was found to be an anomer-inverting transglycosylase which specifically generated α-1,6-glucosidic bonds from β-1,2-glucan donors [2]. EcOpgD and XccOpgD are specific toward β-1,2-glucan and the amino acid residues for recognizing β-1,2-glucan at common subsites between EcOpgD and XccOpgD (subsite –7 to +6) are highly conserved in GH186 [1, 2]. However, the reaction types of EcOpgD and XccOpgD are different from each other [1, 2]. EcOpgD is a β-1,2-glucanase that preferentially generates β-1,2-glucooligosaccharides (Sopns, where n indicates a degree of polymerization, DP) with DPs of 6 and 7 from linear β-1,2-glucan [1]. Final products produced by EcOpgD are Sop6–10, indicating that EcOgpD hydrolyzes Sopns with DPs of 11 and higher [1]. XccOpgD generates only α-1,6-cyclized β-1,2-glucohexadecaose from linear β-1,2-glucan [2]. Almost all family members are found in Pseudomonadota, particularly gamma proteobacteria.

Kinetics and Mechanism

Figure 1. Catalytic center of EcOpgD
Figure 2. Catalytic center of XccOpgD

Optical rotation and NMR analyses indicated that EcOpgD and XccOpgD use anomer-inverting mechanisms [1, 2]. X-ray structural analysis (see below) and mutational analysis suggest that D388 in EcOpgD and the equivalent residue in XccOpgD, D379, directly protonate the scissile glycosidic bond as general acids (Figure 1, 2) [1, 2]. These analyses also suggested that D300 in EcOpgD and the equivalent residue in XccOpgD, D291, act as as general bases to activate the nucleophile via a chain comprising the 4-hydroxy group of the Glc moiety at subsite –1 and two water molecules [1, 2]. In EcOpgD (glucanase), the nucleophile is a water molecule and in XccOpgD (transglycosylase) the nucleophile is the 6-hydroxy group of the terminal Glc moiety at position –16 in the chain [1, 2]. It should be noted that transglycosylation is more typical of anomer-retaining GHs, which use a covalent glycosyl-enzyme intermediate, further highlighting the uniqueness of these GH186 members.

The difference in nucleophiles among GH186 family is probably due to how the nucleophile and the Grotthuss proton relay are stabilized. While W441, which is important for stabilizing nucleophilic water in EcOpgD, is not conserved in GH186, W76, which is important for stacking with the acceptor Glc moiety in XccOpgD is broadly conserved (but not in the clade of EcOpgD) (Figure 2) [1, 2]. Therefore, GH186 seems to be fundamentally an anomer-inverting transglycosylase family. In addition, the Grotthuss proton relay is sequestered (stabilized) not by amino acid sequence but by positioning of the acceptor substrate in XccOpgD, with the result that a water molecule is not suitable as a nucleophile for efficient Grotthuss proton relay. This explains why XccOpgD is a specific transglycosylase [2].

Catalytic Residues

As described above, the identities of the catalytic residues were indicated by X-ray crystallography and supported by site-directed mutagenesis. The general acid and general base of EcOpgD are D388 and D300, respectively, and the equivalent catalytic residues of XccOpgD are D379 and D291, respectively) [1, 2].

Three-dimensional structures

The ligand-free structure of OpgG from E. coli (EcOpgG) was determined at 2.4 Å resolution (PDB 1TXK) [3]. The ligand-free structure of EcOpgD was determined at 2.95 Å resolution (PDB 8IOX) [1]. Michaelis complexes of EcOpgD (D388N, co-crystal), EcOpgG (D361N, soaking) and XccOpgD (D379N, soaking) with β-1,2-glucan were determined at 2.06, 1.81, and 2.25 Å resolutions, respectively (PDB 8IP1, PDB 8IP2, PDB 8X18) [1, 2]. Notably, GH186 is strucuturally unique, i.e. lacks 3-D structural homologs, among all of the GHs families known at the time [1].

Figure 3. The overall Michaelis complex structure of EcOpgG (monomer)

EcOpgG consists of an N-terminal domain (residues 22–388, β-sandwich) and a C-terminal domain (residues 401–511, Ig-like fold) (Figure 3). The two domains are connected with one turn of a 310 helix [1, 3]. The loop region (residues 409-425, Loop A below) in the C-terminal domain of the ligand-free structure organizes into β-strands in the Michaelis complex structure. In the Michaelis complex, the β-strands extend toward the catalytic center of another chain in the dimer to cover the proton transfer pathway from a nucleophile to the general base catalyst [1]. However, the sequence of Loop A is diversified in GH186 family. Indeed, Loop A in EcOpgD sequesters the proton transfer pathway from the solvent, while that of EcOpgG does not completely, which is consistent with the drastically reduced hydrolytic activity of EcOpgG compared with EcOpgD [1]. In addition, the corresponding Loop A of XccOpgD is too short to reach the catalytic center, which makes space to accommodate a β-1,2-glucooligosaccharide acceptor [2].

Family Firsts

First stereochemistry determination
EcOpgD by optical rotation [1].
First general acid residue identification
EcOpgD by X-ray crystallography and site-directed mutagenesis [1].
First general base residue identification
EcOpgD by X-ray crystallography and site-directed mutagenesis [1].
First 3-D structure
EcOpgG by X-ray crystallography [3].

References

  1. Motouchi S, Kobayashi K, Nakai H, and Nakajima M. (2023). Identification of enzymatic functions of osmo-regulated periplasmic glucan biosynthesis proteins from Escherichia coli reveals a novel glycoside hydrolase family. Commun Biol. 2023;6(1):961. DOI:10.1038/s42003-023-05336-6 | PubMed ID:37735577 [Motouchi2023]
  2. Motouchi S, Komba S, Nakai H, and Nakajima M. (2024). Discovery of Anomer-Inverting Transglycosylase: Cyclic Glucohexadecaose-Producing Enzyme from Xanthomonas, a Phytopathogen. J Am Chem Soc. 2024;146(26):17738-17746. DOI:10.1021/jacs.4c02579 | PubMed ID:38957137 [Motouchi2024]
  3. Hanoulle X, Rollet E, Clantin B, Landrieu I, Odberg-Ferragut C, Lippens G, Bohin JP, and Villeret V. (2004). Structural analysis of Escherichia coli OpgG, a protein required for the biosynthesis of osmoregulated periplasmic glucans. J Mol Biol. 2004;342(1):195-205. DOI:10.1016/j.jmb.2004.07.004 | PubMed ID:15313617 [Hanoulle2004]

All Medline abstracts: PubMed