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Difference between revisions of "Glycoside Hydrolase Family 29"

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* [[Author]]: [[User:Gerlind Sulzenbacher|Gerlind Sulzenbacher]]
* [[Author]]: ^^^Gerlind Suzlenbacher^^^
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* [[Responsible Curator]]:  ^^^Steve Withers^^^
 
 
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|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
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== Substrate specificities ==
 
== Substrate specificities ==
The [[glycoside hydrolases]] of this family are exo-acting α-fucosidases from archaeal, bacterial and eukaryotic origin. No other activities have been observed for GH29 family members. So fare the only other CAZY family containing α-fucosidases is family [[GH95]]. The human enzyme FucA1 is of medical interest because its deficiency leads to fucosidosis, an autosomal recessive lysosomal storage disease <cite>1</cite>.
+
The [[glycoside hydrolases]] of this family are [[exo]]-acting α-fucosidases from archaeal, bacterial and eukaryotic origin. No other activities have been observed for GH29 family members. So far the only other CAZY family containing α-fucosidases is family [[GH95]]. The human enzyme FucA1 is of medical interest because its deficiency leads to [http://www.ncbi.nlm.nih.gov/entrez/dispomim.cgi?id=230000 fucosidosis], an autosomal recessive lysosomal storage disease <cite>1</cite>.
 
 
  
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
GH29 α-fucosidases  are [[retaining]] enzymes following a [[classical Koshland double-displacement mechanism]], as first proposed in 1987 for human liver α-fucosidase via burst kinetics experiments and  using methanol as an alternative glycone acceptor to produce methyl-α-L-fucoside <cite>2</cite>. This has been further confirmed by <sup>1</sup>H NMR monitoring of the reaction catalyzed by a α-L-fucosidase from ''Thermus sp.'' <cite>3</cite>, and a α-L-fucosidase from the marine mollusc ''Pecten maximus''<cite>4</cite>, as well as by COSY and <sup>1</sup>H-<sup>13</sup>C NMR spectroscopy analysis of the interglycosidic linkage of disaccharides formed by the transglycosylation action of ''Sulfolobus solfataricus'' α-L-fucosidase, Ssα-fuc <cite>5</cite>. [[GH95]] α-fucosidases, in contrast, operate with inversion of the anomeric configuration.
+
GH29 α-fucosidases  are [[retaining]] enzymes following a [[classical Koshland double-displacement mechanism]], as first proposed in 1987 for human liver α-fucosidase ''via'' burst kinetics experiments and  using methanol as an alternative glycone acceptor to produce methyl α-L-fucoside <cite>2</cite>. This has been further confirmed by <sup>1</sup>H NMR monitoring of the reaction catalyzed by an α-L-fucosidase from ''Thermus sp.'' <cite>3</cite>, and a α-L-fucosidase from the marine mollusc ''Pecten maximus'' <cite>4</cite>, as well as by COSY and <sup>1</sup>H-<sup>13</sup>C NMR spectroscopy analysis of the interglycosidic linkage of disaccharides formed by the [[transglycosylases|transglycosylase]] action of ''Sulfolobus solfataricus'' α-L-fucosidase, Ssα-fuc <cite>5</cite>. [[GH95]] α-fucosidases, in contrast, operate with inversion of the anomeric configuration.
 
 
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
The [[catalytic nucleophile]] in GH29 was first identified in the ''Sulfolobus solfataricus'' α-L-fucosidase, Ssα-fuc, as Asp242 in the sequence VYF<u>'''D'''</u>WWI via chemical rescue of an inactive mutant with sodium azide <cite>6</cite>. Concomitantly the [[catalytic nucleophile]] of ''Thermotoga maritima'' α-L-fucosidase, Tmα-fuc, was confirmed to be Asp224 in the sequence LWN<u>'''D'''</u>MGW through trapping of the 2-deoxy-2-fluorofucosyl-enzyme [[intermediate]] and subsequent peptide mapping via LC-MS/MS technologies, as well as by chemical rescue of an inactive mutant <cite>7</cite>. The trapping of the 2-deoxy-2-fluorofucosyl-enzyme intermediate in Tmα-fuc was corroborated by crystallographic studies <cite>8</cite>. The [[catalytic nucleophile]] of the human enzyme FucA1 has recently been identified as being Asp225 <cite>9</cite>.
+
The [[catalytic nucleophile]] in GH29 was first identified in the ''Sulfolobus solfataricus'' α-L-fucosidase, Ssα-fuc, as Asp242 in the sequence VYF<u>'''D'''</u>WWI via chemical rescue of an inactive mutant with sodium azide <cite>6</cite>. Concomitantly the [[catalytic nucleophile]] of ''Thermotoga maritima'' α-L-fucosidase, Tmα-fuc, was confirmed to be Asp224 in the sequence LWN<u>'''D'''</u>MGW through trapping of the 2-deoxy-2-fluorofucosyl-enzyme [[intermediate]] and subsequent peptide mapping via LC-MS/MS technologies, as well as by chemical rescue of an inactive mutant <cite>7</cite>. The trapping of the 2-deoxy-2-fluorofucosyl-enzyme [[intermediate]] in Tmα-fuc was corroborated by crystallographic studies <cite>8</cite>. The [[catalytic nucleophile]] of the human enzyme FucA1 has recently been identified as being Asp225 <cite>9</cite>.
  
Whereas the [[catalytic nucleophile]] in GH29 has been shown to be a conserved aspartate residue, the identity of the [[general acid/base]] is still controversial.  Structural and mutagenesis studies of Tmα-fuc provided strong evidence for the variant Glu266 being the [[general acid/base]] <cite>8</cite>. In the crystal structure the carboxyl function of this residue is 5.5 Å apart from that of the [[catalytic nucleophile]] Asp224, a distance commonly observed in retaining glycosidases proceeding via a [[classical Koshland double-displacement mechanism]]. Although multiple sequence alignments show that Glu266 is not conserved within GH29, the residue is structurally conserved in two 3-D structures of α-L-fucosidases from ''Bacteroides thetaiotaomicron sp.'', recently deposited in the [http://www.pdb.org/ Protein Data Bank] (accession numbers 3eyp and 3gza). Studies of Ssα-fuc demonstrated that mutation of the Glu residue corresponding in sequence to Tmα-fuc Glu266 scarcely impaired the catalytic activity of the enzyme, whereas the E58G mutant yielded a 4000-fold reduction of ''k<sub>cat</sub>/K<sub>M</sub>'' and could be chemically rescued <cite>10</cite>. In the crystal structure of Tmα-fuc in complex with fucose <cite>8</cite>, the residue corresponding to Ssα-fuc Glu58, Glu66, is found 7.5 Å distant form the [[catalytic nucleophile]] Asp224 and hydrogen bond to the C-3 hydroxyl group of fucose, which altogether makes this residue an unlikely candidate for the function of the [[general acid/base]]. A recent study of the human α-L-fucosidase FucA1, carefully done combining bioinformatics, structural modelling, mutagenesis, chemical rescue with azide and <sup>1</sup>H NMR spectral analysis, identified Glu289 as the [[general acid/base]] <cite>9</cite>. The equivalent residue in Tmα-fuc, Glu281, as inferred from sequence alignment of FucA1 and Tmα-fuc, points to the interior of the (β/α)<sub>8</sub> barrel and lies about 15 Å apart form the catalytic centre.
+
Whereas the [[catalytic nucleophile]] in GH29 has been shown to be a conserved aspartate residue, the identity of the [[general acid/base]] is still controversial.  Structural and mutagenesis studies of Tmα-fuc provided strong evidence for the variant Glu266 being the [[general acid/base]] <cite>8</cite>. In the crystal structure the carboxyl function of this residue is 5.5 Å away from that of the [[catalytic nucleophile]] Asp224, a distance commonly observed in retaining glycosidases proceeding ''via'' a [[classical Koshland double-displacement mechanism]]. Although multiple sequence alignments show that Glu266 is not conserved within GH29, the residue is structurally conserved in two 3-D structures of α-L-fucosidases from ''Bacteroides thetaiotaomicron VPI-5482'', recently deposited in the [http://www.pdb.org/ Protein Data Bank] (PDB accession numbers [{{PDBlink}}3eyp 3eyp] and [{{PDBlink}}3gza 3gza]). Studies of Ssα-fuc demonstrated that mutation of the Glu residue corresponding in sequence to Tmα-fuc Glu266 barely impaired the catalytic activity of the enzyme, whereas a Glu58Gly mutant had a 4000 fold lower ''k<sub>cat</sub>/K<sub>M</sub>'' and could be chemically rescued <cite>10</cite>. In the crystal structure of Tmα-fuc in complex with fucose <cite>8</cite>, the residue corresponding to Ssα-fuc Glu58, Glu66, is found 7.5 Å away from the [[catalytic nucleophile]] Asp224 and hydrogen bonded to the C-3 hydroxyl group of fucose, which altogether makes this residue an unlikely candidate for the function of the [[general acid/base]]. A recent study of the human α-L-fucosidase FucA1, carefully done combining bioinformatics, structural modelling, mutagenesis, chemical rescue with azide and <sup>1</sup>H NMR spectral analysis, identified Glu289 as the [[general acid/base]] <cite>9</cite>. The equivalent residue in Tmα-fuc, Glu281, as inferred from sequence alignment of FucA1 and Tmα-fuc, points to the interior of the (β/α)<sub>8</sub> barrel and lies about 15 Å apart form the catalytic centre.
  
 
Altogether it appears that family GH29 is a quite exceptional CAZy family in that multiple sequence alignments do not allow an unambiguous assignment of the [[general acid/base]].
 
Altogether it appears that family GH29 is a quite exceptional CAZy family in that multiple sequence alignments do not allow an unambiguous assignment of the [[general acid/base]].
 
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
Very few structures are available for GH29 enzyme. The first crystal structure being solved is the one for the α-L-fucosidase from ''T. maritima'', Tmα-fuc. The simultaneous solution of the structures of an enzyme-product complex and of a glycosyl-enzyme intermediate allowed the unambiguous identification of the [[general acid/base]] <cite>8</cite>, as described above. Tmα-fuc assembles as a hexamer and displays a two-domain fold, composed of a catalytic (β/α)<sub>8</sub>-like domain and a C-terminal β-sandwich domain. The two key active site residues are located at the C-terminal ends of strands of β-strands 4 (nucleophile) and 6 (acid/base).
+
The first crystal structure to be solved is that of the α-L-fucosidase from ''T. maritima'', Tmα-fuc (PDB ID [{{PDBlink}}1hl8 1hl8]). The simultaneous solution of the structures of an enzyme-product complex (PDB ID [{{PDBlink}}1odu 1odu]) and of a glycosyl-enzyme [[intermediate]] (PDB ID [{{PDBlink}}1hl9 1hl9]) allowed the unambiguous identification of the [[general acid/base]] <cite>8</cite>, as described above. Tmα-fuc assembles as a hexamer and displays a two-domain fold, composed of a catalytic (β/α)<sub>8</sub>-like domain and a C-terminal β-sandwich domain. The two key active site residues are located at the C-terminal ends of strands β-strands 4 (nucleophile) and 6 (acid/base).
            Normal.dotm  0  0  1  57  326  AFMB  2  1  400  12.0              0  false      21      18 pt  18 pt  0  0      false  false  false
+
Crystallization experiments for the ''S. solfataricus'' α-L-fucosidase, Ssα-fuc, were not very fruitful, but a small angle scattering study has been reported <cite>11</cite>, which suggests a nonameric assembly of the enzyme in solution. Two crystal structures, arising from Structural Genomics initiatives, have been deposited in the [http://www.pdb.org/ Protein Data Bank] for α-L-fucosidases from ''Bacteroides thetaiotaomicron VPI-5482'', with accession numbers [{{PDBlink}}3eyp 3eyp] and [{{PDBlink}}3gza 3gza].            
 
+
The catalytic domain of Tmα-fuc does not adopt the canonical TIM-barrel (β/α)<sub>8</sub> fold, as it lacks helices α5 and α6. Helix α5 is also missing in the structure of one of the ''B. thetaiotaomicron VPI-5482'' α-L-fucosidases, BT3798 (PDB ID [{{PDBlink}}3gza 3gza]), whereas α-L-fucosidase BT2192 (PDB ID [{{PDBlink}}3eyp 3eyp]) from the same organism adopts the canonical TIM-barrel fold. The three structures differ furthermore by the insertion/deletion of a considerable number of additional α-helices, 3<sub>10</sub> helices, and extended surface loop regions. The closest structural homologues of GH29 enzymes within the CAZy classification can be found in [[GH107]], which together with GH29 forms [[Clan]] GH-R. GH29 also bears some structural similarity to families [[GH13]] ([[Clan]] GH-H) and [[GH27]] ([[Clan]] GH-D).
Crystallization experiments for the S. solfataricus SSA-fuc were not very fruitful, but a small angle scattering study has been reported, which suggests nonameric assembly of the enzyme in solution. Two crystal structures, arising for Strucural Genomics initiatives, have been deposited in the PDB for α-L-fucosidases from Bacteroides thetaiotaomicron sp., with accession numbers 3eyp and 3gza.
 
 
 
  
 +
== Transglycosylation and Glycosynthases ==
 +
Transglycosylation activity had been observed in 1987 for human liver α-fucosidase <cite>2</cite>. The first successful transformation of an α-fucosidase into an α-transfucosidase by directed evolution has been reported for ''Thermotoga maritima'' α-fucosidase <cite>12</cite>. α-Fucosidases mutated in the [[catalytic nucleophile]] from both ''Sulfolobus solfataricus'' and ''Thermotoga maritima'' were successfully transformed into a type of synthetic enzyme termed a 'glycosynthase', in this case a fucosynthase, which use β-L-fucopyranosyl azide as donor substrate <cite>13</cite>
  
 
== Family Firsts ==
 
== Family Firsts ==
;First stereochemistry determination: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>Comfort2007</cite>.
+
;First stereochemistry determination: [[retaining|Retention]] of anomeric stereochemistry suggested for human liver α-fucosidase by the formation of methyl α-L-fucoside using methanol as an alternative glycone acceptor <cite>2</cite>. Later confirmed by <sup>1</sup>H NMR for α-L-fucosidase from ''Thermus sp.'' <cite>3</cite>.
;First catalytic nucleophile identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>MikesClassic</cite>.
+
; First [[catalytic nucleophile]] identification : ''Sulfolobus solfataricus'' α-L-fucosidase by azide rescue of an inactivated mutant <cite>6</cite> and confirmed shortly thereafter by labeling of the nucleophile and peptide mapping <cite>7</cite>.
;First general acid/base residue identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>He1999</cite>.
+
; First [[general acid/base]] residue identification : ''Thermotoga maritima'' α-fucosidase by X-ray structural analysis and mutagenesis <cite>8</cite>.
;First 3-D structure: Cite some reference here, with a ''short'' (1-2 sentence) explanation <cite>3</cite>.
+
; First 3-D structure : ''Thermotoga maritima'' α-fucosidase, free  enzyme ([{{PDBlink}}1hl8 PDB 1hl8]), product complex ([{{PDBlink}}1odu PDB 1odu]) and glycosyl-enzyme [[intermediate]] ([{{PDBlink}}1hl9 PDB 1hl9]) <cite>8</cite>.
  
 
== References ==
 
== References ==
Line 70: Line 66:
 
#9 pmid=19072333
 
#9 pmid=19072333
 
#10 pmid=15835922
 
#10 pmid=15835922
 
+
#11 pmid=15207718
</biblio>
+
#12 pmid=17240986           
 +
#13 pmid=19875083
 +
</biblio>  
  
 
[[Category:Glycoside Hydrolase Families|GH029]]
 
[[Category:Glycoside Hydrolase Families|GH029]]

Latest revision as of 13:19, 18 December 2021

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Glycoside Hydrolase Family GH 29
Clan GH-R
Mechanism retaining
Active site residues known
CAZy DB link
https://www.cazy.org/GH29.html


Substrate specificities

The glycoside hydrolases of this family are exo-acting α-fucosidases from archaeal, bacterial and eukaryotic origin. No other activities have been observed for GH29 family members. So far the only other CAZY family containing α-fucosidases is family GH95. The human enzyme FucA1 is of medical interest because its deficiency leads to fucosidosis, an autosomal recessive lysosomal storage disease [1].

Kinetics and Mechanism

GH29 α-fucosidases are retaining enzymes following a classical Koshland double-displacement mechanism, as first proposed in 1987 for human liver α-fucosidase via burst kinetics experiments and using methanol as an alternative glycone acceptor to produce methyl α-L-fucoside [2]. This has been further confirmed by 1H NMR monitoring of the reaction catalyzed by an α-L-fucosidase from Thermus sp. [3], and a α-L-fucosidase from the marine mollusc Pecten maximus [4], as well as by COSY and 1H-13C NMR spectroscopy analysis of the interglycosidic linkage of disaccharides formed by the transglycosylase action of Sulfolobus solfataricus α-L-fucosidase, Ssα-fuc [5]. GH95 α-fucosidases, in contrast, operate with inversion of the anomeric configuration.

Catalytic Residues

The catalytic nucleophile in GH29 was first identified in the Sulfolobus solfataricus α-L-fucosidase, Ssα-fuc, as Asp242 in the sequence VYFDWWI via chemical rescue of an inactive mutant with sodium azide [6]. Concomitantly the catalytic nucleophile of Thermotoga maritima α-L-fucosidase, Tmα-fuc, was confirmed to be Asp224 in the sequence LWNDMGW through trapping of the 2-deoxy-2-fluorofucosyl-enzyme intermediate and subsequent peptide mapping via LC-MS/MS technologies, as well as by chemical rescue of an inactive mutant [7]. The trapping of the 2-deoxy-2-fluorofucosyl-enzyme intermediate in Tmα-fuc was corroborated by crystallographic studies [8]. The catalytic nucleophile of the human enzyme FucA1 has recently been identified as being Asp225 [9].

Whereas the catalytic nucleophile in GH29 has been shown to be a conserved aspartate residue, the identity of the general acid/base is still controversial. Structural and mutagenesis studies of Tmα-fuc provided strong evidence for the variant Glu266 being the general acid/base [8]. In the crystal structure the carboxyl function of this residue is 5.5 Å away from that of the catalytic nucleophile Asp224, a distance commonly observed in retaining glycosidases proceeding via a classical Koshland double-displacement mechanism. Although multiple sequence alignments show that Glu266 is not conserved within GH29, the residue is structurally conserved in two 3-D structures of α-L-fucosidases from Bacteroides thetaiotaomicron VPI-5482, recently deposited in the Protein Data Bank (PDB accession numbers 3eyp and 3gza). Studies of Ssα-fuc demonstrated that mutation of the Glu residue corresponding in sequence to Tmα-fuc Glu266 barely impaired the catalytic activity of the enzyme, whereas a Glu58Gly mutant had a 4000 fold lower kcat/KM and could be chemically rescued [10]. In the crystal structure of Tmα-fuc in complex with fucose [8], the residue corresponding to Ssα-fuc Glu58, Glu66, is found 7.5 Å away from the catalytic nucleophile Asp224 and hydrogen bonded to the C-3 hydroxyl group of fucose, which altogether makes this residue an unlikely candidate for the function of the general acid/base. A recent study of the human α-L-fucosidase FucA1, carefully done combining bioinformatics, structural modelling, mutagenesis, chemical rescue with azide and 1H NMR spectral analysis, identified Glu289 as the general acid/base [9]. The equivalent residue in Tmα-fuc, Glu281, as inferred from sequence alignment of FucA1 and Tmα-fuc, points to the interior of the (β/α)8 barrel and lies about 15 Å apart form the catalytic centre.

Altogether it appears that family GH29 is a quite exceptional CAZy family in that multiple sequence alignments do not allow an unambiguous assignment of the general acid/base.

Three-dimensional structures

The first crystal structure to be solved is that of the α-L-fucosidase from T. maritima, Tmα-fuc (PDB ID 1hl8). The simultaneous solution of the structures of an enzyme-product complex (PDB ID 1odu) and of a glycosyl-enzyme intermediate (PDB ID 1hl9) allowed the unambiguous identification of the general acid/base [8], as described above. Tmα-fuc assembles as a hexamer and displays a two-domain fold, composed of a catalytic (β/α)8-like domain and a C-terminal β-sandwich domain. The two key active site residues are located at the C-terminal ends of strands β-strands 4 (nucleophile) and 6 (acid/base). Crystallization experiments for the S. solfataricus α-L-fucosidase, Ssα-fuc, were not very fruitful, but a small angle scattering study has been reported [11], which suggests a nonameric assembly of the enzyme in solution. Two crystal structures, arising from Structural Genomics initiatives, have been deposited in the Protein Data Bank for α-L-fucosidases from Bacteroides thetaiotaomicron VPI-5482, with accession numbers 3eyp and 3gza. The catalytic domain of Tmα-fuc does not adopt the canonical TIM-barrel (β/α)8 fold, as it lacks helices α5 and α6. Helix α5 is also missing in the structure of one of the B. thetaiotaomicron VPI-5482 α-L-fucosidases, BT3798 (PDB ID 3gza), whereas α-L-fucosidase BT2192 (PDB ID 3eyp) from the same organism adopts the canonical TIM-barrel fold. The three structures differ furthermore by the insertion/deletion of a considerable number of additional α-helices, 310 helices, and extended surface loop regions. The closest structural homologues of GH29 enzymes within the CAZy classification can be found in GH107, which together with GH29 forms Clan GH-R. GH29 also bears some structural similarity to families GH13 (Clan GH-H) and GH27 (Clan GH-D).

Transglycosylation and Glycosynthases

Transglycosylation activity had been observed in 1987 for human liver α-fucosidase [2]. The first successful transformation of an α-fucosidase into an α-transfucosidase by directed evolution has been reported for Thermotoga maritima α-fucosidase [12]. α-Fucosidases mutated in the catalytic nucleophile from both Sulfolobus solfataricus and Thermotoga maritima were successfully transformed into a type of synthetic enzyme termed a 'glycosynthase', in this case a fucosynthase, which use β-L-fucopyranosyl azide as donor substrate [13]

Family Firsts

First stereochemistry determination
Retention of anomeric stereochemistry suggested for human liver α-fucosidase by the formation of methyl α-L-fucoside using methanol as an alternative glycone acceptor [2]. Later confirmed by 1H NMR for α-L-fucosidase from Thermus sp. [3].
First catalytic nucleophile identification
Sulfolobus solfataricus α-L-fucosidase by azide rescue of an inactivated mutant [6] and confirmed shortly thereafter by labeling of the nucleophile and peptide mapping [7].
First general acid/base residue identification
Thermotoga maritima α-fucosidase by X-ray structural analysis and mutagenesis [8].
First 3-D structure
Thermotoga maritima α-fucosidase, free enzyme (PDB 1hl8), product complex (PDB 1odu) and glycosyl-enzyme intermediate (PDB 1hl9) [8].

References

  1. O'Brien JS, Willems PJ, Fukushima H, de Wet JR, Darby JK, Di Cioccio R, Fowler ML, and Shows TB. (1987). Molecular biology of the alpha-L-fucosidase gene and fucosidosis. Enzyme. 1987;38(1-4):45-53. DOI:10.1159/000469189 | PubMed ID:2894306 [1]
  2. White WJ Jr, Schray KJ, Legler G, and Alhadeff JA. (1987). Further studies on the catalytic mechanism of human liver alpha-L-fucosidase. Biochim Biophys Acta. 1987;912(1):132-8. DOI:10.1016/0167-4838(87)90256-1 | PubMed ID:3828350 [2]
  3. Eneyskaya EV, Kulminskaya AA, Kalkkinen N, Nifantiev NE, Arbatskii NP, Saenko AI, Chepurnaya OV, Arutyunyan AV, Shabalin KA, and Neustroev KN. (2001). An alpha-L-fucosidase from Thermus sp. with unusually broad specificity. Glycoconj J. 2001;18(10):827-34. DOI:10.1023/a:1021163720282 | PubMed ID:12441672 [3]
  4. Berteau O, McCort I, Goasdoué N, Tissot B, and Daniel R. (2002). Characterization of a new alpha-L-fucosidase isolated from the marine mollusk Pecten maximus that catalyzes the hydrolysis of alpha-L-fucose from algal fucoidan (Ascophyllum nodosum). Glycobiology. 2002;12(4):273-82. DOI:10.1093/glycob/12.4.273 | PubMed ID:12042250 [4]
  5. Cobucci-Ponzano B, Trincone A, Giordano A, Rossi M, and Moracci M. (2003). Identification of an archaeal alpha-L-fucosidase encoded by an interrupted gene. Production of a functional enzyme by mutations mimicking programmed -1 frameshifting. J Biol Chem. 2003;278(17):14622-31. DOI:10.1074/jbc.M211834200 | PubMed ID:12569098 [5]
  6. Cobucci-Ponzano B, Trincone A, Giordano A, Rossi M, and Moracci M. (2003). Identification of the catalytic nucleophile of the family 29 alpha-L-fucosidase from Sulfolobus solfataricus via chemical rescue of an inactive mutant. Biochemistry. 2003;42(32):9525-31. DOI:10.1021/bi035036t | PubMed ID:12911294 [6]
  7. Tarling CA, He S, Sulzenbacher G, Bignon C, Bourne Y, Henrissat B, and Withers SG. (2003). Identification of the catalytic nucleophile of the family 29 alpha-L-fucosidase from Thermotoga maritima through trapping of a covalent glycosyl-enzyme intermediate and mutagenesis. J Biol Chem. 2003;278(48):47394-9. DOI:10.1074/jbc.M306610200 | PubMed ID:12975375 [7]
  8. Sulzenbacher G, Bignon C, Nishimura T, Tarling CA, Withers SG, Henrissat B, and Bourne Y. (2004). Crystal structure of Thermotoga maritima alpha-L-fucosidase. Insights into the catalytic mechanism and the molecular basis for fucosidosis. J Biol Chem. 2004;279(13):13119-28. DOI:10.1074/jbc.M313783200 | PubMed ID:14715651 [8]
  9. Liu SW, Chen CS, Chang SS, Mong KK, Lin CH, Chang CW, Tang CY, and Li YK. (2009). Identification of essential residues of human alpha-L-fucosidase and tests of its mechanism. Biochemistry. 2009;48(1):110-20. DOI:10.1021/bi801529t | PubMed ID:19072333 [9]
  10. Cobucci-Ponzano B, Mazzone M, Rossi M, and Moracci M. (2005). Probing the catalytically essential residues of the alpha-L-fucosidase from the hyperthermophilic archaeon Sulfolobus solfataricus. Biochemistry. 2005;44(16):6331-42. DOI:10.1021/bi047495f | PubMed ID:15835922 [10]
  11. Rosano C, Zuccotti S, Cobucci-Ponzano B, Mazzone M, Rossi M, Moracci M, Petoukhov MV, Svergun DI, and Bolognesi M. (2004). Structural characterization of the nonameric assembly of an Archaeal alpha-L-fucosidase by synchrotron small angle X-ray scattering. Biochem Biophys Res Commun. 2004;320(1):176-82. DOI:10.1016/j.bbrc.2004.05.149 | PubMed ID:15207718 [11]
  12. Osanjo G, Dion M, Drone J, Solleux C, Tran V, Rabiller C, and Tellier C. (2007). Directed evolution of the alpha-L-fucosidase from Thermotoga maritima into an alpha-L-transfucosidase. Biochemistry. 2007;46(4):1022-33. DOI:10.1021/bi061444w | PubMed ID:17240986 [12]
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