Polysaccharide Lyase Family 42 - Revision history

Alan Cartmell at 16:48, 20 March 2022

2022-03-20T16:48:45Z

Harry Gilbert at 10:38, 12 February 2022

2022-02-12T10:38:12Z

Harry Gilbert at 10:35, 12 February 2022

2022-02-12T10:35:31Z

Harry Gilbert at 10:32, 12 February 2022

2022-02-12T10:32:55Z

Harry Gilbert at 10:28, 12 February 2022

2022-02-12T10:28:25Z

Harry Gilbert at 10:21, 12 February 2022

2022-02-12T10:21:30Z

Harry Gilbert at 10:18, 12 February 2022

2022-02-12T10:18:42Z

Harry Brumer at 16:45, 11 February 2022

2022-02-11T16:45:01Z

Harry Brumer at 16:43, 11 February 2022

2022-02-11T16:43:59Z

Harry Brumer at 16:43, 11 February 2022

2022-02-11T16:43:29Z

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 <!-- RESPONSIBLE CURATORS: Please replace the {{UnderConstruction}} tag below with {{CuratorApproved}} when the page is ready for wider public consumption -->
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 * [[Author]]s: [[User:Alan Cartmell|Alan Cartmell]] and [[User:Harry Gilbert|Harry Gilbert]]
 * [[Responsible Curator]]:  [[User:Alan Cartmell|Alan Cartmell]]

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 == Substrate specificities ==
-Three members of this family (BT3686, BACOVA_0349 and HMPREF9455_02360) have been shown to be exo-α-L-rhamnosidases, targeting rhamnose linked α-1,4 to glucuronic acid (Rha-GlcA) in the complex arabinogalactan protein (AGP) from gum arabic (AGP-GA) <cite>Munoz-Munoz2017</cite>. A fungal member of this family (FoRham1 from ''Fusarium oxysporum 12S'') was shown to cleave the Rha-GlcA linkage in AGP-GA harnessing anti-β-elimination chemistry generating L-rhamnose and C4-C5 unsaturated D-glucuronic acid at the new non-reducing end <cite>Kondo2021</cite>. Three PL42 enzymes were shown to cleave the Rha-GlcA linkage in the highly sulfated AGP from red wine (AGP-Wi) through a β-elimination or exo-lyase mechanism <cite>Munoz-Munoz2021</cite>. Although these three enzymes did not display lyase activity against AGP-GA, one of the CAZymes, BT3686, cleaved the glycan through a glycoside hydrolase mechanism. Thus, BT3686 contains two distinct active sites that cleave glycosidic linkages through a hydrolase and lyase mechanism, respectively. The PL42 family was originally assigned to glycoside hydrolase family GH145. It is evident, however, that the catalytic histidine (see below) in the glycoside hydrolase active site is not highly conserved indicating that many of the GH145 enzymes will not catalyse a hydrolytic reaction. In contrast, there is an extremely high degree of sequence conservation in the lyase active site, including invariant catalytic residues. Thus, β-elimination is likely to be the dominant activity displayed by enzymes in this family. GH145 was therefore reassigned to a polysaccharide lyase family; PL42.
+Three members of this family (BT3686, BACOVA_0349 and HMPREF9455_02360) have been shown to be exo-α-L-rhamnosidases, targeting rhamnose linked α-1,4 to glucuronic acid (Rha-GlcA) in the complex arabinogalactan protein (AGP) from gum arabic (AGP-GA) <cite>Munoz-Munoz2017</cite>. A fungal member of this family (FoRham1 from ''Fusarium oxysporum 12S'') was shown to cleave the Rha-GlcA linkage in AGP-GA harnessing anti-β-elimination chemistry generating L-rhamnose and C4-C5 unsaturated D-glucuronic acid at the new non-reducing end <cite>Kondo2021</cite>. Three PL42 enzymes were shown to cleave the Rha-GlcA linkage in the highly sulfated AGP from red wine (AGP-Wi) through a β-elimination or exo-lyase mechanism <cite>Munoz-Munoz2021</cite>. Although these three enzymes did not display lyase activity against AGP-GA, one of the CAZymes, BT3686, cleaved the glycan through a glycoside hydrolase mechanism. Thus, BT3686 contains two distinct active sites that cleave glycosidic linkages through a hydrolase and lyase mechanism, respectively. The PL42 family was originally assigned to glycoside hydrolase family GH145. It is evident, however, that the catalytic histidine (see below) in the glycoside hydrolase active site is not highly conserved indicating that many of the enzymes in this family will not catalyse a hydrolytic reaction. In contrast, there is an extremely high degree of sequence conservation in the lyase active site, including invariant catalytic residues. Thus, β-elimination is likely to be the dominant activity displayed by enzymes in this family. GH145 was therefore reassigned to a polysaccharide lyase family; PL42.
 == Kinetics and Mechanism ==

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 The β-elimination catalyzed by PL42 enzymes results in the formation of a C4-C5 unsaturated sugar residue at the new non-reducing end. The first step is the neutralization of the acid group in the +1 subsite by a conserved arginine. A histidine abstracts the labile proton at C5. The same histidine is also believed to act as the catalytic acid, protonating the leaving group (L-Rha) resulting in glycosidic bond cleavage <cite>Kondo2021</cite>.
-With respect to the glycoside hydrolase activity displayed by some PL42 enzymes, the catalytic mechanism was explored using BT3686 from ''Bacteroides thetaiotamicron'' and AGP-GA as the substrate. NMR analysis of the reaction revealed the family operates via a retaining mechanism <cite>Munoz-Munoz2017</cite>. Rather than using a standard double displacement mechanism the enzyme is speculatively predicted to perform catalysis via an epoxide intermediate, similar to GH99 enzymes <cite>Thompson2012 Fernandes2018</cite>. BT3686 is proposed to perform catalysis via a substrate assisted mechanism, requiring the carboxyl group of the glucuronic acid and a single catalytic histidine; both acting as an acid/base. This histidine is predicted to deprotonate the O2 of rhamnose, allowing O2 to attack C1 and form an epoxide. Simultaneously the carboxyl group of the glucuronic acid may deprotonate a water molecule generating a hydroxyl group to attach the C1 of rhamnose and allowing protonation of its own O4 thus, leading to glycosidic  bond cleavage <cite>Munoz-Munoz2017</cite>. Further work is needed to confirm the mechanism by which some GH145 enzymes operate through a glycoside hydrolase mechanism.
+With respect to the glycoside hydrolase activity displayed by some PL42 enzymes, the catalytic mechanism was explored using BT3686 from ''Bacteroides thetaiotamicron'' and AGP-GA as the substrate. NMR analysis of the reaction revealed the family operates via a retaining mechanism <cite>Munoz-Munoz2017</cite>. Rather than using a standard double displacement mechanism the enzyme is speculatively predicted to perform catalysis via an epoxide intermediate, similar to GH99 enzymes <cite>Thompson2012 Fernandes2018</cite>. BT3686 is proposed to perform catalysis via a substrate assisted mechanism, requiring the carboxyl group of the glucuronic acid and a single catalytic histidine; both acting as an acid/base. This histidine is predicted to deprotonate the O2 of rhamnose, allowing O2 to attack C1 and form an epoxide. Simultaneously the carboxyl group of the glucuronic acid may deprotonate a water molecule generating a hydroxyl group to attach the C1 of rhamnose and allowing protonation of its own O4 thus, leading to glycosidic  bond cleavage <cite>Munoz-Munoz2017</cite>. Further work is needed to confirm the mechanism by which some PL42 enzymes operate through a glycoside hydrolase mechanism.
 == Catalytic Residues ==
 With respect to the lyase mechanism, of which FoRham1 is the exemplar, X-ray crystallography of enzyme-substrate complexes and mutagenesis studies showed that Arg166 neutralizes the acid group of the substrate and His85 is proposed to act as the catalytic acid-base <cite>Kondo2021</cite>.

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 == Three-dimensional structures ==
-PL42 enzymes comprise a single catalytic domain displaying a seven bladed β-propeller fold. Each blade is composed of four anti parallel β-strands that extend out radially from the central core. The final blade is formed by strands from both the N- and C-terminus of the protein, which is termed as 'molecular velcro' and is believed to add considerable stability to the fold. The glycoside hydrolase active site is located on the posterior surface, while the anterior surface houses the b-elimination or lyase catalytic apparatus. PL42 is distantly related to PL25 and PL24, in which the anterior surface houses the catalytic apparatus <cite>Ulaganathan2017 Ulaganathan2018 </cite>.
+PL42 enzymes comprise a single catalytic domain displaying a seven bladed β-propeller fold. Each blade is composed of four anti parallel β-strands that extend out radially from the central core. The final blade is formed by strands from both the N- and C-terminus of the protein, which is termed as 'molecular velcro' and is believed to add considerable stability to the fold. The glycoside hydrolase active site is located on the posterior surface, while the anterior surface houses the β-elimination or lyase catalytic apparatus. PL42 is distantly related to PL25 and PL24, in which the anterior surface houses the catalytic apparatus <cite>Ulaganathan2017 Ulaganathan2018 </cite>.
 == Family Firsts ==

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 ;First demonstration of lyase activity: FoRham1 from ''Fusarium oxysporum 12S''. Activity shown against AGP-GA derived oligosaccharides by UV absorbance spectroscopy and HPAEC <cite>Kondo2021</cite>.
 ;First catalytic base/acid identification:  FoRham1 His85  was suggested as the catalytic acid/base based upon the crystal structure of the enzyme-substrate complex, residue conservation, mutagenesis and activity analysis (H311A was inactive) <cite>Kondo2021</cite>.
-;First charge neutralizer identification: FoRham1 Arg166 was suggested based on the crystal structure, whiccarboxylate group at the +1 subsite its conservation, mutagenesis and activity analysis (R166A was inactive).;First 3-D structure: FoRham1 from ''Fusarium oxysporum'' 12S <cite>Kondo2021</cite>.
+;First charge neutralizer identification: FoRham1 Arg166 was suggested as the charge neutralizer based on the crystal structure (the proximity of the carboxylate group of glucuronic acid at the +1 subsite to the arginine) its conservation, mutagenesis and activity analysis (R166A was inactive).;First 3-D structure: FoRham1 from ''Fusarium oxysporum'' 12S <cite>Kondo2021</cite>.
 === Glycoside hydrolase activity ===
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 ;First catalytic acid/base residue identification: Predicted to be a histidine <cite>Munoz-Munoz2017</cite>.
 ;Second general acid/base residue identification: Predicted to be provided by the substrate <cite>Munoz-Munoz2017</cite>.
-;First 3-D structure: BT3686, BACINT_00347 and BACCELL_00856 were the first enzymes to have their structures solved from the organisms ''Bacteroides thetaiotaomicron'', ''bacteroides intestinalis'' and ''bacteroides cellulosilyticus'', respectively.  <cite>Munoz-Munoz2017</cite>.
+;First 3-D structure: BT3686, BACINT_00347 and BACCELL_00856 from ''Bacteroides thetaiotaomicron'', ''Bacteroides intestinalis'' and ''Bacteroides cellulosilyticus'', respectively, were the first PL42 enzymes to have their structures solved <cite>Munoz-Munoz2017</cite>.
 == References ==