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Difference between revisions of "Glycoside Hydrolase Family 47"
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== Substrate specificities == | == Substrate specificities == | ||
− | GH47 [[glycoside hydrolases]] are ''[[exo]]-acting '' | + | GH47 [[glycoside hydrolases]] are ''[[exo]]-acting ''α-1,2-mannosidases. Members from this family play important roles in the processing of N-glycans. |
Content is to be added here. | Content is to be added here. | ||
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− | GH47 enzymes are Ca<sup>2+</sup>-dependent, as demonstrated by loss of activity upon addition of the metal binding ligand EDTA, and activity | + | GH47 enzymes are Ca<sup>2+</sup>-dependent, as demonstrated by loss of activity upon addition of the metal binding ligand EDTA, and restoration of activity through subsequent addition of Ca<sup>2+</sup> <cite>Herscovics1988</cite>. ''exo''-α-mannosidases from [[GH38]] and [[GH92]] also require a metal ion for catalysis. |
− | GH47 mannosidases operate through an unusual <sup>3,O</sup>''B''/<sup>3</sup>''S''<sub>1</sub>→<sup>3</sup>''H''<sub>4</sub>→<sup>1</sup>''C''<sub>4</sub> conformational itinerary, supported by both computational <cite>Reilly2006 Reilly2007 Davies2012</cite> and structural studies {list which complexes are informative] <cite>HowellJBC2000 Moremen2005 Davies2012</cite>. Quantum mechanical/molecular modelling calculations have found that the free energy landscape of α-D-mannopyranose is perturbed on-enzyme such that the accessible conformations of the ligand are | + | GH47 mannosidases operate through an unusual <sup>3,O</sup>''B''/<sup>3</sup>''S''<sub>1</sub>→<sup>3</sup>''H''<sub>4</sub>→<sup>1</sup>''C''<sub>4</sub> conformational itinerary, supported by both computational <cite>Reilly2006 Reilly2007 Davies2012</cite> and structural studies {list which complexes are informative] <cite>HowellJBC2000 Moremen2005 Davies2012</cite>. Quantum mechanical/molecular modelling calculations have found that the free energy landscape of α-D-mannopyranose is perturbed on-enzyme such that the accessible conformations of the ligand are altered to those that correlate well with a <sup>3,O</sup>''B''/<sup>3</sup>''S''<sub>1</sub>→<sup>3</sup>''H''<sub>4</sub>→<sup>1</sup>''C''<sub>4</sub> conformational itinerary <cite>Davies2012</cite>. |
== Catalytic Residues == | == Catalytic Residues == | ||
− | Unequivocal assignment of catalytic residues for GH47 α-mannosidases is complicated by the presence of 3 carboxylate-containing residues in the active site each of which could | + | Unequivocal assignment of catalytic residues for GH47 α-mannosidases is complicated by the presence of 3 carboxylate-containing residues in the active site each of which could plausibly fulfill roles as catalytic residues <cite>Howell2000</cite>. Furthermore, all of the plausible catalytic residues complex water, as would be expected of the [[general base]] residue. Thus, it appears that the [[general acid]] residue transmits a proton to the glycosidic oxygen atom through a water molecule. Crystal structures of human ER α-mannosidase I in complex with kifunensine and 1-deoxynojirimycin found that an inverting mechanism was only compatible with Glu599 or Asp463 (Glu435 and Asp275 in ''Saccharomyces'', respectively) acting as the general base <cite>HowellJBC2000</cite>. A computational docking study found Glu599 to be the most likely general base, with Ca<sup>2+</sup> also coordinated to the nucelophilic water molecule <cite>Reilly2002</cite>. Based upon its position on the opposite face of the glycan ring to the potential general base residues in human ER a-mannosidase I, Glu330 (Glu132 in ''Saccharomyces'') is widely believed to act as the general acid <cite>HowellJBC2000</cite>. However, a computational docking study found Asp463 (Asp275 in ''Saccharomyces'') to be the most likely general acid, based upon the assumption that GH47 mannosidases are ''anti''-protonators <cite>Reilly2008</cite>. |
== Three-dimensional structures == | == Three-dimensional structures == |
Revision as of 17:11, 10 January 2013
This page is currently under construction. This means that the Responsible Curator has deemed that the page's content is not quite up to CAZypedia's standards for full public consumption. All information should be considered to be under revision and may be subject to major changes.
- Author: ^^^Rohan Williams^^^
- Responsible Curator: ^^^Spencer Williams^^^
Glycoside Hydrolase Family GHnn | |
Clan | none, (α/α)7 fold |
Mechanism | inverting |
Active site residues | debated |
CAZy DB link | |
https://www.cazy.org/GH47.html |
Substrate specificities
GH47 glycoside hydrolases are exo-acting α-1,2-mannosidases. Members from this family play important roles in the processing of N-glycans.
Content is to be added here.
Kinetics and Mechanism
GH47 mannosidases catalyze glycosidic cleavage with inversion of stereochemistry, as first determined using 1H NMR spectroscopy with Saccharomyces cervisiae α-1,2-mannosidase using Man9GlcNAc as a substrate [1]. Brief listing of mechanism.
GH47 enzymes are Ca2+-dependent, as demonstrated by loss of activity upon addition of the metal binding ligand EDTA, and restoration of activity through subsequent addition of Ca2+ [2]. exo-α-mannosidases from GH38 and GH92 also require a metal ion for catalysis.
GH47 mannosidases operate through an unusual 3,OB/3S1→3H4→1C4 conformational itinerary, supported by both computational [3, 4, 5] and structural studies {list which complexes are informative] [5, 6, 7]. Quantum mechanical/molecular modelling calculations have found that the free energy landscape of α-D-mannopyranose is perturbed on-enzyme such that the accessible conformations of the ligand are altered to those that correlate well with a 3,OB/3S1→3H4→1C4 conformational itinerary [5].
Catalytic Residues
Unequivocal assignment of catalytic residues for GH47 α-mannosidases is complicated by the presence of 3 carboxylate-containing residues in the active site each of which could plausibly fulfill roles as catalytic residues [8]. Furthermore, all of the plausible catalytic residues complex water, as would be expected of the general base residue. Thus, it appears that the general acid residue transmits a proton to the glycosidic oxygen atom through a water molecule. Crystal structures of human ER α-mannosidase I in complex with kifunensine and 1-deoxynojirimycin found that an inverting mechanism was only compatible with Glu599 or Asp463 (Glu435 and Asp275 in Saccharomyces, respectively) acting as the general base [6]. A computational docking study found Glu599 to be the most likely general base, with Ca2+ also coordinated to the nucelophilic water molecule [9]. Based upon its position on the opposite face of the glycan ring to the potential general base residues in human ER a-mannosidase I, Glu330 (Glu132 in Saccharomyces) is widely believed to act as the general acid [6]. However, a computational docking study found Asp463 (Asp275 in Saccharomyces) to be the most likely general acid, based upon the assumption that GH47 mannosidases are anti-protonators [10].
Three-dimensional structures
GH47 enzymes adopt a (α/α)7 barrel fold with a Ca2+ ion coordinated at the base of the barrel that is plugged by a β-hairpin at the C-terminus [8]. The –1 subsite lies in the core of the barrel with Ca2+ coordinating to the 2-OH and 3-OH groups of a ligand (inhibitor or substrate analogue), whose glycan ring is parallel to the barrel upon complexation [6].
The structural basis for differences in N-glycan branch specificity between ER and Golgi GH47 α-mannosidases has been examined through crystallographic studies comparing their binding to N-glycans [11]. The presumed enzyme-product complexes differed in their oligosaccharide conformation such that different oligosaccharide branches, corresponding to those readily cleaved by the respective enzymes, were projected into the active site.
Family Firsts
- First sterochemistry determination
- Saccharomyces cerevisiae α-1,2-mannosidase was shown to be inverting by 1H NMR [1].
- First general base identification
- Unambiguous identification hindered by presence of 3 carboxylate-containing residues in the active site that coordinate ligands through water molecules [8]. Widely believed to be Glu559 in human ER α-mannosidase I (Glu435 in S. cerevisiae) [9].
- First general acid identification
- Unambiguous identification hindered by presence of 3 carboxylate-containing residues in the active site that coordinate ligands through water molecules [8]. Widely believed to be Glu330 in human ER α-mannosidase I (Glu132 in S. cerevisiae) [7], however, a computational study has concluded that Asp463 acts as the general acid in human ER α-mannosidase I (Asp275 in S. cerevisiae) [10].
- First 3-D structure
- Saccharomyces cerevisiae α-1,2-mannosidase [8].
References
- Lipari F, Gour-Salin BJ, and Herscovics A. (1995). The Saccharomyces cerevisiae processing alpha 1,2-mannosidase is an inverting glycosidase. Biochem Biophys Res Commun. 1995;209(1):322-6. DOI:10.1006/bbrc.1995.1506 |
- Jelinek-Kelly S and Herscovics A. (1988). Glycoprotein biosynthesis in Saccharomyces cerevisiae. Purification of the alpha-mannosidase which removes one specific mannose residue from Man9GlcNAc. J Biol Chem. 1988;263(29):14757-63. | Google Books | Open Library
- Mulakala C, Nerinckx W, and Reilly PJ. (2006). Docking studies on glycoside hydrolase Family 47 endoplasmic reticulum alpha-(1-->2)-mannosidase I to elucidate the pathway to the substrate transition state. Carbohydr Res. 2006;341(13):2233-45. DOI:10.1016/j.carres.2006.05.011 |
- Mulakala C, Nerinckx W, and Reilly PJ. (2007). The fate of beta-D-mannopyranose after its formation by endoplasmic reticulum alpha-(1-->2)-mannosidase I catalysis. Carbohydr Res. 2007;342(2):163-9. DOI:10.1016/j.carres.2006.11.012 |
- Thompson AJ, Dabin J, Iglesias-Fernández J, Ardèvol A, Dinev Z, Williams SJ, Bande O, Siriwardena A, Moreland C, Hu TC, Smith DK, Gilbert HJ, Rovira C, and Davies GJ. (2012). The reaction coordinate of a bacterial GH47 α-mannosidase: a combined quantum mechanical and structural approach. Angew Chem Int Ed Engl. 2012;51(44):10997-1001. DOI:10.1002/anie.201205338 |
- Vallee F, Karaveg K, Herscovics A, Moremen KW, and Howell PL. (2000). Structural basis for catalysis and inhibition of N-glycan processing class I alpha 1,2-mannosidases. J Biol Chem. 2000;275(52):41287-98. DOI:10.1074/jbc.M006927200 |
- Karaveg K, Siriwardena A, Tempel W, Liu ZJ, Glushka J, Wang BC, and Moremen KW. (2005). Mechanism of class 1 (glycosylhydrolase family 47) {alpha}-mannosidases involved in N-glycan processing and endoplasmic reticulum quality control. J Biol Chem. 2005;280(16):16197-207. DOI:10.1074/jbc.M500119200 |
- Vallée F, Lipari F, Yip P, Sleno B, Herscovics A, and Howell PL. (2000). Crystal structure of a class I alpha1,2-mannosidase involved in N-glycan processing and endoplasmic reticulum quality control. EMBO J. 2000;19(4):581-8. DOI:10.1093/emboj/19.4.581 |
- Mulakala C and Reilly PJ. (2002). Understanding protein structure-function relationships in Family 47 alpha-1,2-mannosidases through computational docking of ligands. Proteins. 2002;49(1):125-34. DOI:10.1002/prot.10206 |
- Cantú D, Nerinckx W, and Reilly PJ. (2008). Theory and computation show that Asp463 is the catalytic proton donor in human endoplasmic reticulum alpha-(1-->2)-mannosidase I. Carbohydr Res. 2008;343(13):2235-42. DOI:10.1016/j.carres.2008.05.026 |
- Tempel W, Karaveg K, Liu ZJ, Rose J, Wang BC, and Moremen KW. (2004). Structure of mouse Golgi alpha-mannosidase IA reveals the molecular basis for substrate specificity among class 1 (family 47 glycosylhydrolase) alpha1,2-mannosidases. J Biol Chem. 2004;279(28):29774-86. DOI:10.1074/jbc.M403065200 |