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Difference between revisions of "Glycoside Hydrolase Family 77"

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== Substrate specificities ==
 
== Substrate specificities ==
[[Glycoside hydrolase]] family GH77 is the member of the α-amylase [[clans|clan]] [[GH-H]] <cite>Cantarel2009</cite>, together with [[GH13]] and [[GH70]] <cite>MacGregor2001</cite>. The family is monospecific with the 4-α-glucanotransferase (EC [{{EClink}}2.4.1.25 2.4.1.25]), that is known as disproportionating enzyme (D-enzyme) in plants <cite>Takaha1993</cite> or amylomaltase in bacteria <cite>Terada1999</cite> and archaeons <cite>Kaper2005</cite>. Around 2,000 members <cite>Lombard2014</cite> originates almost exclusively from Bacteria; and the family contains also a few tens of additional sequences from each Archaea and Eucarya (plants and green algae).
+
[[Glycoside hydrolase]] family GH77 is a member of the α-amylase [[clans|clan]] [[GH-H]] <cite>Cantarel2009</cite>, together with [[GH13]] and [[GH70]] <cite>MacGregor2001</cite>. The family is monospecific with the 4-α-glucanotransferase (EC [{{EClink}}2.4.1.25 2.4.1.25]), that is known as disproportionating enzyme (D-enzyme) in plants <cite>Takaha1993</cite> or amylomaltase in bacteria <cite>Terada1999</cite> and archaeons <cite>Kaper2005</cite>. Around 2,000 members <cite>Lombard2014</cite> are known that originate mostly from Bacteria; the family also contains a few tens of additional sequences from each Archaea and Eucarya (plants and green algae). Only slightly above 1% of the family members have been biochemically characterized <cite>Lombard2014</cite>.  
  
Amylomaltase catalyses the glucan-chain transfer from one α-1,4-glucan to another α-1,4-glucan (or to 4-hydroxyl group of glucose) or within a single linear glucan molecule to produce a cyclic α-1,4-glucan with degree of polymerization starting from 17 <cite>Takaha1993,Terada1999,Kaper2005</cite>. Cyclodextrin glucanotransferase, a member of the α-amylase family [[GH13]], also produces cyclic α-1,4-glucans, but with a small degree of polymerization (6-8), called cyclodextrins <cite>Leemhuis2010</cite>.
+
Amylomaltase catalyses glucan-chain transfer from one α-1,4-glucan to another α-1,4-glucan (or to 4-hydroxyl group of glucose) or within a single linear glucan molecule to produce a cyclic α-1,4-glucan with degree of polymerization starting from 17 <cite>Takaha1993,Terada1999,Kaper2005</cite>. Cyclodextrin glucanotransferase, a member of the α-amylase family [[GH13]], also produces cyclic α-1,4-glucans, but with a small degree of polymerization (6-8), called cyclodextrins <cite>Leemhuis2010</cite>.
  
Five tertiary structures have been determined and only slightly above 1% of the family members have already been biochemically characterized <cite>Lombard2014</cite>. The main structural feature that discriminates the family GH77 amylomaltases from typical α-amylase family [[GH13]] members is the lack of domain C <cite>Przylas2000a</cite>  that succeeds the catalytic (β/α)8-barrel (TIM-barrel) in the family [[GH13]]. The eight-fold symmetry of the catalytic barrel is in the family GH77 disrupted by several insertions between the barrel β-strands that form the so-called subdomains B1, B2 and B3 <cite>Przylas2000a</cite>. Subdomain B1 consists of a highly twisted four-stranded antiparallel β-sheet with two α-helices and it is also present in other enzymes from the α-amylase [[clans|clan]] [[GH-H]] (known as domain B). Subdomain B2 has predominantly an α-helical structure and it is unique to amylomaltases. Subdomain B3 could have a role of domain C from the α-amylase family <cite>Przylas2000a</cite>.
+
== Kinetics and Mechanism ==
 +
The GH77 members are proposed to be retaining enzymes that are believed to employ the [[classical Koshland double-displacement mechanism]], as used in the related [[clan]] [[GH-H]] member family [[GH13]] <cite>Uitdehaag1999</cite>.
  
Interestingly, primary structures of amylomaltases from borreliae contain unique sequence features <cite>Machovic2003</cite>, i.e. natural mutations in functionally important positions from conserved sequence regions. The most important and remarkable is represented by otherwise extremely well-conserved and functional arginine in position i-2 with respect to the catalytic nucleophile that is replaced naturally by a lysine <cite>Machovic2003</cite>. It is worth mentioning that this arginine positioned two residues before the catalytic nucleophile in the conserved sequence region II was considered to belong to the four residues conserved invariantly throughout the α-amylase family <cite>Janecek2002</cite>. Its substitution is therefore of a special interest because the GH77 protein from ''Borrelia burgdorferi'' does exhibit the real amylomaltase activity <cite>Godany2008</cite>. Since, however, the lysine could eventually play the role of the original arginine, it is not possible to say unambiguously that the catalytic triad alone (aspartic acid, glutamic acid and aspartic acid at strands β4, β5 and β7, respectively, of the catalytic TIM-barrel) is enough for a GH-H protein to be a real functional member of the α-amylase family <cite>Godany2008</cite>. There are several additional putative amylomaltases from various borreliae available; some of them possess the Arg-to-Lys mutation and some of them not, indicating the group of borreliae may occupy an outstanding position in evolution of this 4-α-glucanotransferase family.
+
Reaction products have been analysed for several family GH77 enzymes by TLC (mainly) and HPLC, including the D-enzyme from potato <cite>Takaha1993</cite> as well as amylomaltases from ''Clostridium butyricum'' <cite>Goda1997</cite>, ''Thermus aquaticus'' <cite>Terada1999</cite>, ''Aquifex aeolicus'' <cite>Bhuiyan2003</cite>, ''Pyrobaculum aerophilum'' <cite>Kaper2005</cite>, ''Thermus thermophilus'' <cite>Kaper2007</cite> and ''Borrelia burgdorferi'' <cite>Godany2008</cite>, but the kinetics were determined only for a few, e.g., <cite>Bhuiyan2003,Kaper2005,Kaper2007</cite>.
  
In plants
+
== Catalytic Residues ==
 +
The family GH77 4-α-glucanotransferases fold into a (β/α)<sub>8</sub>-barrel with the catalytic machinery consisting of a strand β4-aspartic acid (catalytic nucleophile), β5-glutamic acid (proton donor) and β7-aspartic acid (transition-state stabilizer). For example these are Asp293, Glu340 and Asp395 in the amylomaltase from ''Thermus aquaticus'' <cite>Przylas2000a</cite>. The somewhat unusual conformations exhibited mainly by the supposed catalytic nucleophile (Asp293) have been explained by the high experimental pH of 9.0 used during crystallization <cite>Przylas2000b</cite>. The catalytic triad is supported by a later site-directed mutagenesis study <cite>Kaper2007</cite>. All the family GH77 4-α-glucanotransferases share the 4-7 conserved sequence regions <cite>Machovic2003,Godany2008</cite> characteristic for the α-amylase [[clans|clan]] [[GH-H]] <cite>Janecek2002</cite>.
  
== Kinetics and Mechanism ==
+
== Three-dimensional structures ==
The GH77 members employ the retaining reaction mechanism as used in the family [[GH13]].
+
Five 3-D structures have been solved for the following family GH77 members: (i) the amylomaltases from ''Thermus aquaticus'' <cite>Przylas2000a</cite>, ''Aquifex aeolicus'' (unpublished; PDB ID [{{PDBlink}}1tz7 1tz7]), ''Thermus thermophilus'' <cite>Barends2007</cite> and ''Thermus brockianus'' <cite>Jung2011</cite>; and (ii) the D-enzyme from potato (unpublished; PDB ID [{{PDBlink}}1x1n 1x1n]). The crystallization of the amylomaltase from ''Corynebacterium glutamicum'' has also been reported <cite>Srisimarat2013</cite>.
 +
 
 +
The main structural feature that discriminates the family GH77 amylomaltases from typical α-amylase family [[GH13]] members is the lack of domain C <cite>Przylas2000a</cite>  that succeeds the catalytic (β/α)<sub>8</sub>-barrel (TIM-barrel) in the family [[GH13]] enzymes. The eight-fold symmetry of the catalytic barrel in the family GH77 is disrupted by several insertions between the barrel β-strands that form the so-called subdomains B1, B2 and B3 <cite>Przylas2000a</cite>. Subdomain B1 consists of a highly twisted four-stranded antiparallel β-sheet with two α-helices and is also present in other enzymes from the α-amylase [[clans|clan]] [[GH-H]] (known as domain B). Subdomain B2 has predominantly an α-helical structure and it is unique to amylomaltases. Subdomain B3 could have a role of domain C from the α-amylase family <cite>Przylas2000a</cite>.
  
== Catalytic Residues ==
+
Interestingly, primary structures of amylomaltases from borreliae contain unique sequence features <cite>Machovic2003</cite>, i.e. natural mutations in functionally important positions from conserved sequence regions. The most important and remarkable one is represented by otherwise extremely well-conserved and functional arginine in position i-2 with respect to the catalytic nucleophile that is replaced by a lysine <cite>Machovic2003</cite>. It is worth mentioning that this arginine positioned two residues before the catalytic nucleophile in the conserved sequence region II was considered to belong to the four residues conserved invariantly (along with the catalytic triad) throughout the α-amylase family <cite>Janecek2002</cite>. Its substitution is therefore of a special interest because the GH77 protein from ''Borrelia burgdorferi'' exhibits amylomaltase activity <cite>Godany2008</cite>. Since, however, the lysine could play the role of the original arginine, it is not possible to say unambiguously that the catalytic triad alone (aspartic acid, glutamic acid and aspartic acid at strands β4, β5 and β7, respectively, of the catalytic TIM-barrel) is enough for a GH-H protein to be a functional member of the α-amylase family <cite>Godany2008</cite>. There are several additional putative amylomaltases from various borreliae available; some of them possess the Arg-to-Lys mutation, indicating the borreliae enzymes may occupy an outstanding position in evolution of this 4-α-glucanotransferase family GH77 <cite>Kuchtova2015</cite>.
They fold into a (β/α)8-barrel with the catalytic machinery consisting of a strand β4-aspartic acid (catalytic nucleophile), β5-glutamic acid (proton donor) and β7-aspartic acid (transition-state stabilizer). These are, e.g., the Asp293, Glu340 and Asp395 in the amylomaltase from ''Thermus aquaticus'' <cite>Przylas2000a</cite>. All the family GH77 4-α-glucanotransferases share the 4-7 conserved sequence regions <cite>Machovic2003,Godany2008</cite> characteristic for the entire α-amylase [[clans|clan]] [[GH-H]] <cite>Janecek2002</cite>.  
 
  
== Three-dimensional structures ==
+
In plants particularly a longer version of D-enzyme (DPE1) was identified and named DPE2 <cite>Lloyd2004,Lu2004</cite>. It was recently described also in certain bacteria <cite>Kuchtova2015</cite>. It usually contains a ~140 amino acid residues long insert within the catalytic GH77 TIM barrel and two copies of a starch-binding domain of family [{{CAZyDBlink}}CBM20.html CBM20] succeeded by a short coiled coil motif positioned N-terminally <cite>Steichen2008</cite>. Interestingly, removing the insert leads to inactivation of the DPE2 although the insert itself has nothing to do with the catalytic action of the enzyme <cite>Ruzanski2013</cite>.
The five above-mentioned 3-D structures have been solved for the following family GH77 members: (i) the amylomaltases from ''Thermus aquaticus'' <cite>Przylas2000a</cite>, ''Aquifex aeolicus'' (unpublished; PDB ID [{{PDBlink}}1tz7 1tz7]), ''Thermus thermophilus'' <cite>Barends2007</cite> and ''Thermus brockianus'' <cite>Jung2011</cite>; and (ii) the D-enzyme from potato (unpublished; PDB ID [{{PDBlink}}1x1n 1x1n]).
 
  
 
== Family Firsts ==
 
== Family Firsts ==
;First stereochemistry determination: Cite some reference here, with a ''short'' (1-2 sentence) explanation.
+
;First stereochemistry determination: There is no direct evidence for the stereochemistry of hydrolysis of the glucosidic bond in the reaction of any family GH77 4-α-glucanotransferase. HPLC analyses of reaction products reported for amylomaltases from, e.g., ''Aquifex aeolicus'' <cite>Bhuiyan2003</cite>, ''Pyrobaculum aerophilum'' <cite>Kaper2005</cite> and ''Thermus thermophilus'' <cite>Kaper2007</cite> was used to propose a retaining mechanism assumed in analogy with the mechanism confirmed in α-amylase family [[GH13]].
;First catalytic nucleophile identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation.
+
;First [[catalytic nucleophile]] identification: Asp293, was identified as a catalytic nucleophile in the amylomaltase from ''Thermus thermophilus'' on the basis of mutant enzymes (D293N and D293A) that exhibited greatly reduced disproportionation activity <cite>Kaper2007</cite>.
;First general acid/base residue identification: Cite some reference here, with a ''short'' (1-2 sentence) explanation.
+
;First [[general acid/base]] residue identification: The catalytic proton donor, Glu340, was identified as a catalytic residue in the amylomaltase from ''Thermus thermophilus'' by demonstration of a greatly reduced disproportionation activity of the E340Q and E340A mutant enzymes <cite>Kaper2007</cite>.
 
;First 3-D structure: The first 3-D structure of a GH77 member was that of the amylomaltase from ''Thermus aquaticus'' solved first as a free enzyme (PDB ID [{{PDBlink}}1cwy 1cwy]) <cite>Przylas2000a</cite> and subsequently also as a complex with acarbose (PDB ID [{{PDBlink}}1esw 1esw]) <cite>Przylas2000b</cite>.
 
;First 3-D structure: The first 3-D structure of a GH77 member was that of the amylomaltase from ''Thermus aquaticus'' solved first as a free enzyme (PDB ID [{{PDBlink}}1cwy 1cwy]) <cite>Przylas2000a</cite> and subsequently also as a complex with acarbose (PDB ID [{{PDBlink}}1esw 1esw]) <cite>Przylas2000b</cite>.
  
Line 64: Line 65:
 
#Leemhuis2010 pmid=19763564
 
#Leemhuis2010 pmid=19763564
 
#Przylas2000a pmid=10677288
 
#Przylas2000a pmid=10677288
#Machovic2003 Machovic M, and Janecek S. '' The invariant residues in the α-amylase family: just the catalytic triad.'' Biologia 2003; 58(6) 1127-32. ([http://imb.savba.sk/~janecek/Papers/PDF/Biologia_03.pdf  PDF])
+
#Machovic2003 Machovic M, and Janecek S. '' The invariant residues in the α-amylase family: just the catalytic triad.'' Biologia 2003; 58(6):1127-32. ([http://imb.savba.sk/~janecek/Papers/PDF/Biologia_03.pdf  PDF])
#Janecek2002 Janecek S. ''How many conserved sequence regions are there in the α-amylase family?'' Biologia 2002; 57(Suppl. 11) 29-41. ([http://biologia.savba.sk/Suppl_11/Janecek.pdf PDF])
+
#Janecek2002 Janecek S. ''How many conserved sequence regions are there in the α-amylase family?'' Biologia 2002; 57(Suppl. 11):29-41. ([http://biologia.savba.sk/Suppl_11/Janecek.pdf PDF])
 
#Godany2008 pmid=18494783
 
#Godany2008 pmid=18494783
 +
#Kuchtova2015 pmid=26006747
 +
#Lloyd2004 pmid=15034166
 +
#Lu2004 pmid=14593480
 +
#Steichen2008 pmid=18499663
 +
#Ruzanski2013 pmid=23950181
 +
#Uitdehaag1999 pmid=10331869
 +
#Goda1997 pmid=9353929
 +
#Bhuiyan2003 Bhuiyan SH, Kitaoka M, and  Hayashi K. ''A cycloamylose-forming hyperthermostable 4-α-glucanotransferase of Aquifex aeolicus expressed in Escherichia coli.'' Journal of Molecular Catalysis B: Enzymatic 2003; 22:45-53. ([http://dx.doi.org/10.1016/S1381-1177(03)00005-5 DOI: 10.1016/S1381-1177(03)00005-5])
 +
#Kaper2007 pmid=17407266
 +
#Przylas2000b pmid=11082203
 
#Barends2007 pmid=17420245
 
#Barends2007 pmid=17420245
 
#Jung2011 pmid=21117235
 
#Jung2011 pmid=21117235
#Przylas2000b pmid=11082203
 
 
#Srisimarat2013 pmid=23989149
 
#Srisimarat2013 pmid=23989149
#Hoon-Hanks2012 pmid=22672337
 
#vanderMaarel2013 pmid=23465909
 
  
 
</biblio>
 
</biblio>
 
[[Category:Glycoside Hydrolase Families|GH077]]
 
[[Category:Glycoside Hydrolase Families|GH077]]

Latest revision as of 13:20, 18 December 2021

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Glycoside Hydrolase Family GH77
Clan GH-H
Mechanism retaining
Active site residues known
CAZy DB link
https://www.cazy.org/GH77.html


Substrate specificities

Glycoside hydrolase family GH77 is a member of the α-amylase clan GH-H [1], together with GH13 and GH70 [2]. The family is monospecific with the 4-α-glucanotransferase (EC 2.4.1.25), that is known as disproportionating enzyme (D-enzyme) in plants [3] or amylomaltase in bacteria [4] and archaeons [5]. Around 2,000 members [6] are known that originate mostly from Bacteria; the family also contains a few tens of additional sequences from each Archaea and Eucarya (plants and green algae). Only slightly above 1% of the family members have been biochemically characterized [6].

Amylomaltase catalyses glucan-chain transfer from one α-1,4-glucan to another α-1,4-glucan (or to 4-hydroxyl group of glucose) or within a single linear glucan molecule to produce a cyclic α-1,4-glucan with degree of polymerization starting from 17 [3, 4, 5]. Cyclodextrin glucanotransferase, a member of the α-amylase family GH13, also produces cyclic α-1,4-glucans, but with a small degree of polymerization (6-8), called cyclodextrins [7].

Kinetics and Mechanism

The GH77 members are proposed to be retaining enzymes that are believed to employ the classical Koshland double-displacement mechanism, as used in the related clan GH-H member family GH13 [8].

Reaction products have been analysed for several family GH77 enzymes by TLC (mainly) and HPLC, including the D-enzyme from potato [3] as well as amylomaltases from Clostridium butyricum [9], Thermus aquaticus [4], Aquifex aeolicus [10], Pyrobaculum aerophilum [5], Thermus thermophilus [11] and Borrelia burgdorferi [12], but the kinetics were determined only for a few, e.g., [5, 10, 11].

Catalytic Residues

The family GH77 4-α-glucanotransferases fold into a (β/α)8-barrel with the catalytic machinery consisting of a strand β4-aspartic acid (catalytic nucleophile), β5-glutamic acid (proton donor) and β7-aspartic acid (transition-state stabilizer). For example these are Asp293, Glu340 and Asp395 in the amylomaltase from Thermus aquaticus [13]. The somewhat unusual conformations exhibited mainly by the supposed catalytic nucleophile (Asp293) have been explained by the high experimental pH of 9.0 used during crystallization [14]. The catalytic triad is supported by a later site-directed mutagenesis study [11]. All the family GH77 4-α-glucanotransferases share the 4-7 conserved sequence regions [12, 15] characteristic for the α-amylase clan GH-H [16].

Three-dimensional structures

Five 3-D structures have been solved for the following family GH77 members: (i) the amylomaltases from Thermus aquaticus [13], Aquifex aeolicus (unpublished; PDB ID 1tz7), Thermus thermophilus [17] and Thermus brockianus [18]; and (ii) the D-enzyme from potato (unpublished; PDB ID 1x1n). The crystallization of the amylomaltase from Corynebacterium glutamicum has also been reported [19].

The main structural feature that discriminates the family GH77 amylomaltases from typical α-amylase family GH13 members is the lack of domain C [13] that succeeds the catalytic (β/α)8-barrel (TIM-barrel) in the family GH13 enzymes. The eight-fold symmetry of the catalytic barrel in the family GH77 is disrupted by several insertions between the barrel β-strands that form the so-called subdomains B1, B2 and B3 [13]. Subdomain B1 consists of a highly twisted four-stranded antiparallel β-sheet with two α-helices and is also present in other enzymes from the α-amylase clan GH-H (known as domain B). Subdomain B2 has predominantly an α-helical structure and it is unique to amylomaltases. Subdomain B3 could have a role of domain C from the α-amylase family [13].

Interestingly, primary structures of amylomaltases from borreliae contain unique sequence features [15], i.e. natural mutations in functionally important positions from conserved sequence regions. The most important and remarkable one is represented by otherwise extremely well-conserved and functional arginine in position i-2 with respect to the catalytic nucleophile that is replaced by a lysine [15]. It is worth mentioning that this arginine positioned two residues before the catalytic nucleophile in the conserved sequence region II was considered to belong to the four residues conserved invariantly (along with the catalytic triad) throughout the α-amylase family [16]. Its substitution is therefore of a special interest because the GH77 protein from Borrelia burgdorferi exhibits amylomaltase activity [12]. Since, however, the lysine could play the role of the original arginine, it is not possible to say unambiguously that the catalytic triad alone (aspartic acid, glutamic acid and aspartic acid at strands β4, β5 and β7, respectively, of the catalytic TIM-barrel) is enough for a GH-H protein to be a functional member of the α-amylase family [12]. There are several additional putative amylomaltases from various borreliae available; some of them possess the Arg-to-Lys mutation, indicating the borreliae enzymes may occupy an outstanding position in evolution of this 4-α-glucanotransferase family GH77 [20].

In plants particularly a longer version of D-enzyme (DPE1) was identified and named DPE2 [21, 22]. It was recently described also in certain bacteria [20]. It usually contains a ~140 amino acid residues long insert within the catalytic GH77 TIM barrel and two copies of a starch-binding domain of family CBM20 succeeded by a short coiled coil motif positioned N-terminally [23]. Interestingly, removing the insert leads to inactivation of the DPE2 although the insert itself has nothing to do with the catalytic action of the enzyme [24].

Family Firsts

First stereochemistry determination
There is no direct evidence for the stereochemistry of hydrolysis of the glucosidic bond in the reaction of any family GH77 4-α-glucanotransferase. HPLC analyses of reaction products reported for amylomaltases from, e.g., Aquifex aeolicus [10], Pyrobaculum aerophilum [5] and Thermus thermophilus [11] was used to propose a retaining mechanism assumed in analogy with the mechanism confirmed in α-amylase family GH13.
First catalytic nucleophile identification
Asp293, was identified as a catalytic nucleophile in the amylomaltase from Thermus thermophilus on the basis of mutant enzymes (D293N and D293A) that exhibited greatly reduced disproportionation activity [11].
First general acid/base residue identification
The catalytic proton donor, Glu340, was identified as a catalytic residue in the amylomaltase from Thermus thermophilus by demonstration of a greatly reduced disproportionation activity of the E340Q and E340A mutant enzymes [11].
First 3-D structure
The first 3-D structure of a GH77 member was that of the amylomaltase from Thermus aquaticus solved first as a free enzyme (PDB ID 1cwy) [13] and subsequently also as a complex with acarbose (PDB ID 1esw) [14].

References

  1. Cantarel BL, Coutinho PM, Rancurel C, Bernard T, Lombard V, and Henrissat B. (2009). The Carbohydrate-Active EnZymes database (CAZy): an expert resource for Glycogenomics. Nucleic Acids Res. 2009;37(Database issue):D233-8. DOI:10.1093/nar/gkn663 | PubMed ID:18838391 [Cantarel2009]
  2. MacGregor EA, Janecek S, and Svensson B. (2001). Relationship of sequence and structure to specificity in the alpha-amylase family of enzymes. Biochim Biophys Acta. 2001;1546(1):1-20. DOI:10.1016/s0167-4838(00)00302-2 | PubMed ID:11257505 [MacGregor2001]
  3. Takaha T, Yanase M, Okada S, and Smith SM. (1993). Disproportionating enzyme (4-alpha-glucanotransferase; EC 2.4.1.25) of potato. Purification, molecular cloning, and potential role in starch metabolism. J Biol Chem. 1993;268(2):1391-6. | Google Books | Open Library PubMed ID:7678257 [Takaha1993]
  4. Terada Y, Fujii K, Takaha T, and Okada S. (1999). Thermus aquaticus ATCC 33923 amylomaltase gene cloning and expression and enzyme characterization: production of cycloamylose. Appl Environ Microbiol. 1999;65(3):910-5. DOI:10.1128/AEM.65.3.910-915.1999 | PubMed ID:10049841 [Terada1999]
  5. Kaper T, Talik B, Ettema TJ, Bos H, van der Maarel MJ, and Dijkhuizen L. (2005). Amylomaltase of Pyrobaculum aerophilum IM2 produces thermoreversible starch gels. Appl Environ Microbiol. 2005;71(9):5098-106. DOI:10.1128/AEM.71.9.5098-5106.2005 | PubMed ID:16151092 [Kaper2005]
  6. Lombard V, Golaconda Ramulu H, Drula E, Coutinho PM, and Henrissat B. (2014). The carbohydrate-active enzymes database (CAZy) in 2013. Nucleic Acids Res. 2014;42(Database issue):D490-5. DOI:10.1093/nar/gkt1178 | PubMed ID:24270786 [Lombard2014]
  7. Leemhuis H, Kelly RM, and Dijkhuizen L. (2010). Engineering of cyclodextrin glucanotransferases and the impact for biotechnological applications. Appl Microbiol Biotechnol. 2010;85(4):823-35. DOI:10.1007/s00253-009-2221-3 | PubMed ID:19763564 [Leemhuis2010]
  8. Uitdehaag JC, Mosi R, Kalk KH, van der Veen BA, Dijkhuizen L, Withers SG, and Dijkstra BW. (1999). X-ray structures along the reaction pathway of cyclodextrin glycosyltransferase elucidate catalysis in the alpha-amylase family. Nat Struct Biol. 1999;6(5):432-6. DOI:10.1038/8235 | PubMed ID:10331869 [Uitdehaag1999]
  9. Goda SK, Eissa O, Akhtar M, and Minton NP. (1997). Molecular analysis of a Clostridium butyricum NCIMB 7423 gene encoding 4-alpha-glucanotransferase and characterization of the recombinant enzyme produced in Escherichia coli. Microbiology (Reading). 1997;143 ( Pt 10):3287-3294. DOI:10.1099/00221287-143-10-3287 | PubMed ID:9353929 [Goda1997]
  10. Bhuiyan SH, Kitaoka M, and Hayashi K. A cycloamylose-forming hyperthermostable 4-α-glucanotransferase of Aquifex aeolicus expressed in Escherichia coli. Journal of Molecular Catalysis B: Enzymatic 2003; 22:45-53. (DOI: 10.1016/S1381-1177(03)00005-5)

    [Bhuiyan2003]
  11. Kaper T, Leemhuis H, Uitdehaag JC, van der Veen BA, Dijkstra BW, van der Maarel MJ, and Dijkhuizen L. (2007). Identification of acceptor substrate binding subsites +2 and +3 in the amylomaltase from Thermus thermophilus HB8. Biochemistry. 2007;46(17):5261-9. DOI:10.1021/bi602408j | PubMed ID:17407266 [Kaper2007]
  12. Godány A, Vidová B, and Janecek S. (2008). The unique glycoside hydrolase family 77 amylomaltase from Borrelia burgdorferi with only catalytic triad conserved. FEMS Microbiol Lett. 2008;284(1):84-91. DOI:10.1111/j.1574-6968.2008.01191.x | PubMed ID:18494783 [Godany2008]
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