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Difference between revisions of "Glycoside Hydrolase Family 9"

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* [[Author]]s: [[User:David Wilson|David Wilson]] and [[User:Breeanna Urbanowicz|Breeanna Urbanowicz]]
* [[Author]]s: ^^^David Wilson^^^ and ^^^Breeanna Urbanowicz^^^
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* [[Responsible Curator]]:  [[User:David Wilson|David Wilson]]
* [[Responsible Curator]]:  ^^^David Wilson^^^
 
 
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|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
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| colspan="2" |http://www.cazy.org/fam/GH9.html
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== Substrate specificities ==
 
== Substrate specificities ==
GH Family 9 is an inverting glycohydrolase family that mainly contains cellulases and is the second largest cellulase family. It contains mainly endoglucanases with a few processive endoglucanases. All of the processive endoglucanases contain a family 3c CBM rigidly attached to the C-terminus of the family 9 catalytic domain (cd) <cite>Sakon1997</cite>. This domain is part of the active site and is essential for processivity <cite>Sakon1997</cite>.  CBM3c domains bind weakly to cellulose as they lack several of the conserved aromatic residues that are important for cellulose binding in family 3a and family 3b members <cite>Tormo1996</cite>.  All known plant cellulases belong to family 9, and most of the other members are  eubacterial although there are two archael members and some fungal, earthworm,  arthropod, chordate, echinoderma and molusk members. There are two subgroups in family 9, E1 which contains only cellulases from bacteria, including ones from both aerobes and anaeobes,  and E2 which includes some bacterial and all nonbacterial cellulases <cite>Tomme1995</cite>. An evolutionary study shows that the eucaryote members contain two monophyletic groups that are amcient; one including all animal members and the other including all plant members <cite>Davison2005</cite>. All known  processive endoglucanase genes are in subgroup E1.
+
Members of family GH9 are mainly cellulases ([{{EClink}}3.2.1.4 EC 3.2.1.4]), including primarily endo-glucanases and a few processive endo-glucanases. Indeed, as one of the first glycoside hydrolase families classified by hydrophobic cluster analysis, GH9 was previously known as "Cellulase Family E" <cite>Henrissat1989 Gilkes1991</cite>. More recently, certain GH9 members from ''Clostridia'' <cite>Ravachol2016</cite> and ''Bacteroides'' <cite>Larsbrink2014 Foley2019</cite> have been shown to be endo-xyloglucanases ([{{EClink}}3.2.1.151 EC 3.2.1.151]) or mixed-linkage endo-glucanases ([{{EClink}}3.2.1.73 EC 3.2.1.73])Exo-beta-glucosaminidases ([{{EClink}}3.2.1.165 EC 3.2.1.165]) are also found in this family <cite>Honda2016 Wu2018</cite>.
  
=== Plant GH9 Enzymes ===
+
All of the processive endoglucanases contain a family 3c CBM rigidly attached to the C-terminus of the GH9 catalytic domain (cd) <cite>Sakon1997</cite>. This domain is part of the active site and is essential for processivity <cite>Sakon1997</cite>.  [[CBM3]]c domains bind weakly to cellulose as they lack several of the conserved aromatic residues that are important for cellulose binding in family 3a and family 3b members <cite>Tormo1996</cite>.  All known plant cellulases belong to GH9, and most of the other members are eubacterial although there are two archael members and some fungal, earthworm,  arthropod, chordate, echinoderma and molusk members. There are two subgroups in GH9, E1 which contains only cellulases from bacteria, including ones from both aerobes and anaeobes, and E2 which includes some bacterial and all nonbacterial cellulases <cite>Tomme1995</cite>. An evolutionary study shows that the eucaryote members contain two monophyletic groups that are ancient; one including all animal members and the other including all plant members <cite>Davison2005</cite>. All known processive endoglucanase genes are in subgroup E1.
Early reports described the existence of plant "cellulases" or EGases <cite>Hall1963</cite>.  Subsequently, cellulases have been shown to be associated with plant cell wall restructuring during cell expansion, the wall disassembly that accompanies processes such as fruit ripening and abscission( reviewed in <cite>Campillo1999 Rose1999 Molhoj2002</cite>) and cellulose biosynthesis <cite>Nicol1998 Lane2001 Sato2001</cite>. The amino acid sequences of the first plant "cellulases"/endo-ß-1,4-glucanases revealed that these enzymes belong to the CAZy family GH9 glycoside hydrolases <cite>Henrissat1991</cite>.
+
Most plant GH9 enzymes studied to date are endoglucanases ("cellulases", EC [{{EClink}}3.2.1.4 3.2.1.4]) with little or no activity on crystalline cellulose, but with discernible activity on soluble cellulose derivatives, including carboxymethyl cellulose (CMC), phosphoric acid swollen non-crystalline cellulose, and numerous plant polysaccharides including xylan, 1,3-1,4-ß-glucan, xyloglucan, and glucomannan <cite>Master2004 YoshidaKomae2006 Ohmiya2000 Woolley2001 Urbanowicz2007</cite>. Due to their ubiquity and large numbers, the phylogeny of plant GH9 enzymes has been further sub-divided into three classes <cite>UrbanowiczBennett2007</cite>, which are described in detail on the [[Glycoside_Hydrolase_Family_9/Plant_endoglucanases|plant GH9 endoglucanase subpage]].
 
 
Most plant "cellulases" studied to date are endoglucanases (EC 3.2.1.4) with low or no activity on crystalline cellulose, but with discernible activity on soluble cellulose derivatives, including carboxymethyl cellulose (CMC), phosphoric acid swollen non-crystalline cellulose, and numerous plant polysaccharides including xylan, 1,3-1,4-ß-glucan, xyloglucan, and glucomannan <cite> Master2004 YoshidaKomae2006 Ohmiya2000 Woolley2001 Urbanowicz2007</cite>. The inability of plant “cellulases” to hydrolyze crystaline cellulose is distinct from microbial cellulases, whose modular structure and synergistic action with  other enzymes facilitates effective degradation of crystalline cellulose.  ''In muro'', the substrates of plant cellulases likely include xyloglucan, xylans, and non-crystalline cellulose, especially amorphous regions of cellulose where the microfibrils may be interwoven with xyloglucan.
 
 
 
==== Plant GH9 subfamilies ====
 
In the model plant'' Arabidopsis thaliana'', 25 different GH9 coding regions have been identified. Phylogenic analysis of the deduced amino acid sequences group the proteins into nine classes or three subfamilies <cite>Molhoj2002 Libertini2004 Urbanowicz2007 UrbanowiczBennett2007</cite>. Three distinct types of GH9 proteins are present in plants. Class A proteins are membrane-anchored, Class B proteins are secreted, and Class C proteins are also secreted but contain a family 49 carbohydrate binding module (CBM49) <cite>Urbanowicz2007</cite>. Class A plant EGases have been reported to lack tryptophans corresponding to substrate binding at subsites -4, -3, and -2 in ''T. fusca ''Cel9A <cite>Master2004</cite>. Class C EGases are the only plant EGases to date that contain a tryptophan residue corresponding to the one in subsite -2 in TfCel9A <cite>Urbanowicz2007 Master2004</cite>.  This tryptophan has been shown to be important for hydrolysis in TfCel9A, and the enzyme retains less than 10% of its normal activity on polymeric cellulose substrates, and less than 1% of wild type activity on cellohexaose when the Trp is replaced by another amino acid <cite>Li2007 Master2004</cite>.
 
 
 
===== Class A =====
 
The Class A EGases are integral type II membrane proteins with a GH9 catalytic core that lack a canonical secretion signal sequence. These enzymes are predicted to have a high degree of N-glycosylation and a long amino-terminal extension with a membrane-spanning domain that anchors the protein to the plasma membrane and/or to intracellular organelles <cite>Molhoj2002 Brummell1997</cite>. Membrane anchored EGases were first described in studies of the ''KORRIGAN'' (''KOR'') genes in<sup> </sup>''Arabidopsis thaliana'', which showed that they encode EGases that are required for normal cellulose synthesis or assembly.  Plants with mutant alleles of the ''KOR1'' gene are dwarfed, with decreased cellulose content and crystallinity <cite>Molhoj2002 Szyjanowicz2004 Takahashi2009</cite>.  The role of the Class A EGases in plants is not known.  However, the KOR proteins have been proposed to cleave sitosterol-b-glucoside primers from the growing cellulose polymer, or may have a role in editing incorrectly formed growing microfibrils <cite>Peng2002</cite>. More recently, it has been shown that during cell expansion, KOR1 is cycled from the plasma membrane through intracellular compartments, comprising both<sup> </sup>the Golgi apparatus and early endosomes; however the role of KOR1 in cellulose biosynthesis remains to be determined <cite>Robert2005</cite>.  The catalytic domain of PttCel9A, a Class A GH9 enzyme that is upregulated during secondary cell wall synthesis in ''Populus tremula x tremuloides'', has been biochemically characterized and shown to hydrolyse a narrow range of substrates ''in vitro'' including CMC, phosphoric acid swollen cellulose and cellulose oligosaccharides (DP≥5) <cite>Master2004 Rudsander2008</cite>.
 
 
 
===== Class B =====
 
Class B proteins are the most common form of plant Egases and are associated with virtually all stages of plant growth and development.  These enzymes have a GH9 catalytic domain and a signal sequence for ER targeting and secretion.  Different isoforms are expressed during fruit ripening, in abscission zones, in reproductive organ development, and in expanding cells <cite>Brummel1999 Brummel1997 Kalaitzis1999 Shani1997</cite>.  Numerous studies, especially in tomato, have also shown that many class B EGases are under hormonal control <cite>Catala1997 Brummell1997 Bonghi1998</cite>.
 
 
 
===== Class C =====
 
Plant Class C GH9 enzymes are the least studied. These proteins are predicted to have a signal sequence followed by a GH9 catalytic domain and a long carboxyl-terminal extension, which contains a CBM49 that has been shown to bind to crystalline cellulose ''in vitro'' <cite>Urbanowicz2007 UrbanowiczBennett2007</cite>.  CBMs are necessary for activity on crystalline substrates and may promote hydrolysis by increasing the local enzyme concentration at the substrate surface as well as modifying cellulose microfibril structure (for review see <cite>Boraston2004</cite>). The catalytic domain (CD) SlGH9C1 from tomato is promiscuous and can effectively hydrolyze artificial cellulosic polymers, cellulose oligosaccharides, and several plant cell wall polysaccharides <cite>Urbanowicz2007</cite>.  Nevertheless, the activity of the full length, modular enzyme has still not been characterized.  A Class C EGase from rice, OsCel9A, has been shown to be post-translationaly modified at the linker region to yield a 51 kDa GH9 CD and a CBM49, and it was suggested that the cleavage is necessary for function <cite>YoshidaImaizumi2006</cite>.  The OsCel9A CD also displays a broad substrate range and was able to hydrolyze CMC, phosphoric acid-swollen cellulose, mixed linkage 1,3-1,4-ß-glucan, xylan, glucomannan, cellooligosaccharides (DP≥3) and 1,4-ß-xylohexaose <cite>YoshidaKomae2006</cite>. For Information regarding nomenclature of plant GH9 enzymes please see Urbanowicz et al 2007 <cite>UrbanowiczBennett2007</cite>.
 
  
 
== Kinetics and Mechanism ==
 
== Kinetics and Mechanism ==
The processive endoglucanase, Cel9A from Thermobifda fusca, has high activity on bacterial cellulose and is the only cellulase tested that can degrade crystalline regions in bacterial cellulose by itself although it prefers amorphous regions <cite>Chen2007</cite>.  A related cellulase in ''Clostridium phytofermentans'', which is the only family 9 cellulase encoded in its genome, has been shown to be essential for cellulose degradation by this organism. This is the only case where a single cellulase has been shown to be essential for growth on cellulose <cite>Tolonen2009</cite>.     
+
[[GH9]] enzymes operate with [[inverting|inversion]] of anomeric stereochemistry. The processive endoglucanase, Cel9A from ''Thermobifda fusca'', has high activity on bacterial cellulose and is the only cellulase tested that can degrade crystalline regions in bacterial cellulose by itself although it prefers amorphous regions <cite>Chen2007</cite>.  A related cellulase in ''Clostridium phytofermentans'', which is the only family 9 cellulase encoded in its genome, has been shown to be essential for cellulose degradation by this organism. This is the only case where a single cellulase has been shown to be essential for growth on cellulose <cite>Tolonen2009</cite>.     
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
There is a conserved Glu residue that functions as the catalytic acid and two conserved Asp residues that bind the catalytic water, with one functioning as the catalytic base and  mutation of the other also greatly reduces activity on all substrates <cite>Zhou2004</cite>.
+
There is a conserved Glu residue that functions as a catalytic [[general acid]] and two conserved Asp residues that bind the catalytic water, with one functioning as the catalytic [[general base]]; mutation of the other also greatly reduces activity on all substrates <cite>Zhou2004</cite>. Mutation of the conserved Glu to Ala, Gly or Gln reduced activity to less than >0.5% of WT on all forms of cellulose but the Ala and Gly mutant enzymes had higher than WT activity on dinitrophenyl-cellobioside which has a good leaving group, proving that this residue functions as the catalytic acid <cite>Zhou2004</cite>. Mutation of either of two conserved Asp residues that bound the catalytic water to Ala or Asn reduced activity to less then 2% of WT on all cellulosic substrates. However, only one of the Ala mutant enzymes showed azide rescue proving that it was the actual catalytic base <cite>Li2007</cite>.
  
 
== Three-dimensional structures ==
 
== Three-dimensional structures ==
All known family 9 cd structures have an ( a / a ) 6 barrel fold that contains an open active site cleft that contains at least six sugar binding subsites -4 to +2 <cite>Sakon1997 Geurin2002</cite>. In processive endoglucanases the catalytic domain is joined to a family 3c CBM that is aligned with the active site cleft <cite>Sakon1997</cite>.
+
All reported GH9 catalytic domain structures have an (a/a)<sub>6</sub> barrel fold that contains an open active site cleft that contains at least six sugar binding subsites -4 to +2 <cite>Sakon1997 Geurin2002 Foley2019</cite>. In processive endoglucanases the catalytic domain is joined to a family 3c carbohydrate-binding module that is aligned with the active site cleft <cite>Sakon1997</cite>.
  
 
== Family Firsts ==
 
== Family Firsts ==
;First sterochemistry determination: The steriospecificity of three family 9 cellulases were all determined to be inverting by NMR <cite>Gebler1992</cite>.
+
;First stereochemistry determination: The stereospecificity of three family 9 cellulases were all determined to be inverting by NMR <cite>Gebler1992</cite>.
  
;First catalytic nucleophile identification: Asp 58 in ''T. fusca'' Cel9A was shown to be the catalytic nucleophile by site directed mutagenesis and azide rescue <cite>Li2007</cite>.
+
;First [[general base]] identification: Asp 58 in ''T. fusca'' Cel9A was shown to be the [[general base]] by site directed mutagenesis and azide rescue <cite>Li2007</cite>.
  
;First general acid/base residue identification: Glu555 was shown to be the catalytic acid in ''C. thermocellum'' CelD by site directed mutagenesis <cite>Chavaux1962</cite>.
+
;First [[general acid]] residue identification: Glu555 was shown to be the catalytic acid in ''C. thermocellum'' CelD by site directed mutagenesis <cite>Chavaux1992</cite>.
  
 
;First 3-D structure: The structure of endocellulase CelD from ''Clostridium thermocellum'' was determined by X-ray crystallography (PDB ID [{{PDBlink}}1clc 1clc]) <cite>Lascombe1995</cite>.
 
;First 3-D structure: The structure of endocellulase CelD from ''Clostridium thermocellum'' was determined by X-ray crystallography (PDB ID [{{PDBlink}}1clc 1clc]) <cite>Lascombe1995</cite>.
 
  
 
== References ==
 
== References ==
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#Tolonen2009 pmid=19775243
 
#Tolonen2009 pmid=19775243
 
#Gebler1992 pmid=1618761
 
#Gebler1992 pmid=1618761
#Lascombe1995 Lascombe, M.B., Souchon, H., Juy, M., Alzari, P.M. Three-Dimensional Structure of Endoglucanase D  at 1.9 Angstroms Resolution. Deposited 1995, unpublished.
+
#Lascombe1995 Lascombe, M.B., Souchon, H., Juy, M., Alzari, P.M. Three-Dimensional Structure of Endoglucanase D  at 1.9 Angstroms Resolution. Deposited 1995, unpublished. [{{PDBlink}}1clc PDB ID 1clc]
#Hall1963 pmid=14097721
 
#Campillo1999 pmid=10417876
 
#Rose1999 pmid=10322557
 
#Molhoj2002 pmid=12514237
 
#Nicol1998 pmid=9755157
 
#Lane2001 pmid=11351091
 
#Sato2001 pmid=11266576
 
#Henrissat1991 pmid=1747104
 
 
#Master2004 pmid=15287736
 
#Master2004 pmid=15287736
 
#YoshidaKomae2006 pmid=17056618
 
#YoshidaKomae2006 pmid=17056618
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#Woolley2001 pmid=11762160
 
#Woolley2001 pmid=11762160
 
#Urbanowicz2007 pmid=17322304
 
#Urbanowicz2007 pmid=17322304
#Libertini2004 pmid=15170254
 
 
#UrbanowiczBennett2007 pmid=17687051
 
#UrbanowiczBennett2007 pmid=17687051
#Peng2002 pmid=11778054
+
#Henrissat1989 pmid=2806912
#Szyjanowicz pmid=14871312
+
#Gilkes1991 pmid=1886523
#Robert2005 pmid=16284310
+
#Chavaux1992 pmid=1537833
#Takahashi2009 pmid=19398462
+
#Foley2019 pmid=30668971
#Rudsander2008 pmid=18402467
+
#Larsbrink2014 pmid=24463512
#Brummell1997 pmid=9037162
+
#Ravachol2016 pmid=26946939
#Brummel1999 pmid=10480385
+
 
#Kalaitzis1999 pmid=10555309
+
#Wu2018 pmid=30084401
#Shani1997 pmid=9290636
 
#Catala1997 pmid=9301092
 
#Bonghi1998 pmid=1281437
 
#Boraston2004 pmid=15214846
 
#YoshidaImaizumi2006 pmid=17056619
 
  
 +
#Honda2016 pmid=26621872
 
</biblio>
 
</biblio>
  
 
[[Category:Glycoside Hydrolase Families|GH009]]
 
[[Category:Glycoside Hydrolase Families|GH009]]

Latest revision as of 13:18, 18 December 2021

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Glycoside Hydrolase Family GH9
Clan not assigned
Mechanism inverting
Active site residues known/known
CAZy DB link
https://www.cazy.org/GH9.html


Substrate specificities

Members of family GH9 are mainly cellulases (EC 3.2.1.4), including primarily endo-glucanases and a few processive endo-glucanases. Indeed, as one of the first glycoside hydrolase families classified by hydrophobic cluster analysis, GH9 was previously known as "Cellulase Family E" [1, 2]. More recently, certain GH9 members from Clostridia [3] and Bacteroides [4, 5] have been shown to be endo-xyloglucanases (EC 3.2.1.151) or mixed-linkage endo-glucanases (EC 3.2.1.73). Exo-beta-glucosaminidases (EC 3.2.1.165) are also found in this family [6, 7].

All of the processive endoglucanases contain a family 3c CBM rigidly attached to the C-terminus of the GH9 catalytic domain (cd) [8]. This domain is part of the active site and is essential for processivity [8]. CBM3c domains bind weakly to cellulose as they lack several of the conserved aromatic residues that are important for cellulose binding in family 3a and family 3b members [9]. All known plant cellulases belong to GH9, and most of the other members are eubacterial although there are two archael members and some fungal, earthworm, arthropod, chordate, echinoderma and molusk members. There are two subgroups in GH9, E1 which contains only cellulases from bacteria, including ones from both aerobes and anaeobes, and E2 which includes some bacterial and all nonbacterial cellulases [10]. An evolutionary study shows that the eucaryote members contain two monophyletic groups that are ancient; one including all animal members and the other including all plant members [11]. All known processive endoglucanase genes are in subgroup E1. Most plant GH9 enzymes studied to date are endoglucanases ("cellulases", EC 3.2.1.4) with little or no activity on crystalline cellulose, but with discernible activity on soluble cellulose derivatives, including carboxymethyl cellulose (CMC), phosphoric acid swollen non-crystalline cellulose, and numerous plant polysaccharides including xylan, 1,3-1,4-ß-glucan, xyloglucan, and glucomannan [12, 13, 14, 15, 16]. Due to their ubiquity and large numbers, the phylogeny of plant GH9 enzymes has been further sub-divided into three classes [17], which are described in detail on the plant GH9 endoglucanase subpage.

Kinetics and Mechanism

GH9 enzymes operate with inversion of anomeric stereochemistry. The processive endoglucanase, Cel9A from Thermobifda fusca, has high activity on bacterial cellulose and is the only cellulase tested that can degrade crystalline regions in bacterial cellulose by itself although it prefers amorphous regions [18]. A related cellulase in Clostridium phytofermentans, which is the only family 9 cellulase encoded in its genome, has been shown to be essential for cellulose degradation by this organism. This is the only case where a single cellulase has been shown to be essential for growth on cellulose [19].

Catalytic Residues

There is a conserved Glu residue that functions as a catalytic general acid and two conserved Asp residues that bind the catalytic water, with one functioning as the catalytic general base; mutation of the other also greatly reduces activity on all substrates [20]. Mutation of the conserved Glu to Ala, Gly or Gln reduced activity to less than >0.5% of WT on all forms of cellulose but the Ala and Gly mutant enzymes had higher than WT activity on dinitrophenyl-cellobioside which has a good leaving group, proving that this residue functions as the catalytic acid [20]. Mutation of either of two conserved Asp residues that bound the catalytic water to Ala or Asn reduced activity to less then 2% of WT on all cellulosic substrates. However, only one of the Ala mutant enzymes showed azide rescue proving that it was the actual catalytic base [21].

Three-dimensional structures

All reported GH9 catalytic domain structures have an (a/a)6 barrel fold that contains an open active site cleft that contains at least six sugar binding subsites -4 to +2 [5, 8, 22]. In processive endoglucanases the catalytic domain is joined to a family 3c carbohydrate-binding module that is aligned with the active site cleft [8].

Family Firsts

First stereochemistry determination
The stereospecificity of three family 9 cellulases were all determined to be inverting by NMR [23].
First general base identification
Asp 58 in T. fusca Cel9A was shown to be the general base by site directed mutagenesis and azide rescue [21].
First general acid residue identification
Glu555 was shown to be the catalytic acid in C. thermocellum CelD by site directed mutagenesis [24].
First 3-D structure
The structure of endocellulase CelD from Clostridium thermocellum was determined by X-ray crystallography (PDB ID 1clc) [25].

References

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  1. Error fetching PMID 2806912: [Henrissat1989]
  2. Error fetching PMID 1886523: [Gilkes1991]
  3. Error fetching PMID 26946939: [Ravachol2016]
  4. Error fetching PMID 24463512: [Larsbrink2014]
  5. Error fetching PMID 30668971: [Foley2019]
  6. Error fetching PMID 26621872: [Honda2016]
  7. Error fetching PMID 30084401: [Wu2018]
  8. Error fetching PMID 9334746: [Sakon1997]
  9. Error fetching PMID 8918451: [Tormo1996]
  10. Error fetching PMID 8540419: [Tomme1995]
  11. Error fetching PMID 15703240: [Davison2005]
  12. Error fetching PMID 15287736: [Master2004]
  13. Error fetching PMID 17056618: [YoshidaKomae2006]
  14. Error fetching PMID 11069690: [Ohmiya2000]
  15. Error fetching PMID 11762160: [Woolley2001]
  16. Error fetching PMID 17322304: [Urbanowicz2007]
  17. Error fetching PMID 17687051: [UrbanowiczBennett2007]
  18. Chen, Arthur J. Stipanovic, William T. Winter, David B. Wilson and Young-Jun Kim. Effect of digestion by pure cellulases on crystallinity and average chain length for bacterial and microcrystalline celluloses. Cellulose 2007: 14: 283-293.

    [Chen2007]
  19. Error fetching PMID 19775243: [Tolonen2009]
  20. Error fetching PMID 15274620: [Zhou2004]
  21. Error fetching PMID 17369336: [Li2007]
  22. Error fetching PMID 11884144: [Geurin2002]
  23. Error fetching PMID 1618761: [Gebler1992]
  24. Error fetching PMID 1537833: [Chavaux1992]
  25. Lascombe, M.B., Souchon, H., Juy, M., Alzari, P.M. Three-Dimensional Structure of Endoglucanase D at 1.9 Angstroms Resolution. Deposited 1995, unpublished. PDB ID 1clc

    [Lascombe1995]

All Medline abstracts: PubMed