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PDBsum entry 1us3
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Contents |
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* Residue conservation analysis
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PDB id:
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Hydrolase
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Title:
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Native xylanase10c from cellvibrio japonicus
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Structure:
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Endo-beta-1,4-xylanase precursor. Chain: a. Fragment: carbohydrate binding module and catalytic module, residues (86-606). Synonym: xylanase10c. Engineered: yes
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Source:
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Cellvibrio japonicus. Organism_taxid: 155077. Expressed in: escherichia coli. Expression_system_taxid: 562.
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Resolution:
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1.85Å
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R-factor:
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0.162
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R-free:
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0.195
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Authors:
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G.Pell,L.Szabo,S.J.Charnock,H.Xie,T.M.Gloster,G.J.Davies,H.J.Gilbert
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Key ref:
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G.Pell
et al.
(2004).
Structural and biochemical analysis of Cellvibrio japonicus xylanase 10C: how variation in substrate-binding cleft influences the catalytic profile of family GH-10 xylanases.
J Biol Chem,
279,
11777-11788.
PubMed id:
DOI:
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Date:
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17-Nov-03
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Release date:
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18-Dec-03
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PROCHECK
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Headers
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References
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Q59675
(XY10C_CELJA) -
Endo-beta-1,4-xylanase Xyn10C from Cellvibrio japonicus
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Seq:
Struc:
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606 a.a.
482 a.a.
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Key: |
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PfamA domain |
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Secondary structure |
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CATH domain |
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Enzyme class:
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E.C.3.2.1.8
- endo-1,4-beta-xylanase.
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Reaction:
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Endohydrolysis of 1,4-beta-D-xylosidic linkages in xylans.
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DOI no:
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J Biol Chem
279:11777-11788
(2004)
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PubMed id:
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Structural and biochemical analysis of Cellvibrio japonicus xylanase 10C: how variation in substrate-binding cleft influences the catalytic profile of family GH-10 xylanases.
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G.Pell,
L.Szabo,
S.J.Charnock,
H.Xie,
T.M.Gloster,
G.J.Davies,
H.J.Gilbert.
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ABSTRACT
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Microbial degradation of the plant cell wall is the primary mechanism by which
carbon is utilized in the biosphere. The hydrolysis of xylan, by
endo-beta-1,4-xylanases (xylanases), is one of the key reactions in this
process. Although amino acid sequence variations are evident in the substrate
binding cleft of "family GH10" xylanases (see afmb.cnrs-mrs.fr/CAZY/),
their biochemical significance is unclear. The Cellvibrio japonicus GH10
xylanase CjXyn10C is a bi-modular enzyme comprising a GH10 catalytic module and
a family 15 carbohydrate-binding module. The three-dimensional structure at 1.85
A, presented here, shows that the sequence joining the two modules is
disordered, confirming that linker sequences in modular glycoside hydrolases are
highly flexible. CjXyn10C hydrolyzes xylan at a rate similar to other previously
described GH10 enzymes but displays very low activity against
xylooligosaccharides. The poor activity on short substrates reflects weak
binding at the -2 subsite of the enzyme. Comparison of CjXyn10C with other
family GH10 enzymes reveals "polymorphisms" in the substrate binding
cleft including a glutamate/glycine substitution at the -2 subsite and a
tyrosine insertion in the -2/-3 glycone region of the substrate binding cleft,
both of which contribute to the unusual properties of the enzyme. The
CjXyn10C-substrate complex shows that Tyr-340 stacks against the xylose residue
located at the -3 subsite, and the properties of Y340A support the view that
this tyrosine plays a pivotal role in substrate binding at this location. The
generic importance of using CjXyn10C as a template in predicting the biochemical
properties of GH10 xylanases is discussed.
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Selected figure(s)
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Figure 5.
FIG. 5. Schematic representation of the protein-ligand
interactions in the -4 to -1 subsites of CjXyn10C. Only direct
hydrogen-bonding residues (with H-bond distances of <3.2
Å) and important aromatic/hydrophobic side chains
mentioned in the text are shown.
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Figure 7.
FIG. 7. Schematic of xylan hydrolysis by the xylan
degrading enzymes of C. japonicus. The structures shown for
CjXyn11A and CjXyn11B are representative bacterial GH11 enzymes
from Bacillus agaradhaerens and Nonomuraea flexuosa,
respectively, the structure shown for CjAbf51A is from
Geobacillus stearothermophilus, and the structure shown for
CjXyn10D is of the homologous (93% similar) enzyme CmXyn10B from
C. mixtus. The enzymes CjAbf51A, CjGlcA67A, and CjXyn10C are all
attached to the outer membrane of the bacterium, whereas
CjXyn10A, CjXyn11A, and CjXyn11B are secreted into the culture
medium (40, 42, 43). The sugar side chains released by the  -glucuronidase and
arabinofuranosidase, respectively, are likely to be transported
into the cytoplasm of C. japonicus. (The depiction of the plant
cell wall is reproduced from Carpita and Gieaut (44). Reproduced
with permission from Blackwell Publishing, ©1993.)
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2004,
279,
11777-11788)
copyright 2004.
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Figures were
selected
by an automated process.
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Literature references that cite this PDB file's key reference
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PubMed id
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Reference
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J.L.Brás,
A.Cartmell,
A.L.Carvalho,
G.Verzé,
E.A.Bayer,
Y.Vazana,
M.A.Correia,
J.A.Prates,
S.Ratnaparkhe,
A.B.Boraston,
M.J.Romão,
C.M.Fontes,
and
H.J.Gilbert
(2011).
Structural insights into a unique cellulase fold and mechanism of cellulose hydrolysis.
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Proc Natl Acad Sci U S A,
108,
5237-5242.
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PDB code:
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M.Lafond,
A.Tauzin,
V.Desseaux,
E.Bonnin,
e.l.-.H.Ajandouz,
and
T.Giardina
(2011).
GH10 xylanase D from Penicillium funiculosum: biochemical studies and xylooligosaccharide production.
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Microb Cell Fact,
10,
20.
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A.Pollet,
J.A.Delcour,
and
C.M.Courtin
(2010).
Structural determinants of the substrate specificities of xylanases from different glycoside hydrolase families.
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Crit Rev Biotechnol,
30,
176-191.
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C.Hervé,
A.Rogowski,
A.W.Blake,
S.E.Marcus,
H.J.Gilbert,
and
J.P.Knox
(2010).
Carbohydrate-binding modules promote the enzymatic deconstruction of intact plant cell walls by targeting and proximity effects.
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Proc Natl Acad Sci U S A,
107,
15293-15298.
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S.Qin,
and
H.X.Zhou
(2010).
Selection of near-native poses in CAPRI rounds 13-19.
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Proteins,
78,
3166-3173.
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D.Dodd,
and
I.K.Cann
(2009).
Enzymatic deconstruction of xylan for biofuel production.
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Glob Change Biol Bioenergy,
1,
2.
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J.Y.Sun,
M.Q.Liu,
and
X.Y.Weng
(2009).
Hydrolytic properties of a hybrid xylanase and its parents.
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Appl Biochem Biotechnol,
152,
428-439.
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A.Cartmell,
E.Topakas,
V.M.Ducros,
M.D.Suits,
G.J.Davies,
and
H.J.Gilbert
(2008).
The Cellvibrio japonicus mannanase CjMan26C displays a unique exo-mode of action that is conferred by subtle changes to the distal region of the active site.
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J Biol Chem,
283,
34403-34413.
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PDB codes:
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J.G.Berrin,
and
N.Juge
(2008).
Factors affecting xylanase functionality in the degradation of arabinoxylans.
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Biotechnol Lett,
30,
1139-1150.
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V.Solomon,
A.Teplitsky,
S.Shulami,
G.Zolotnitsky,
Y.Shoham,
and
G.Shoham
(2007).
Structure-specificity relationships of an intracellular xylanase from Geobacillus stearothermophilus.
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Acta Crystallogr D Biol Crystallogr,
63,
845-859.
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PDB code:
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F.J.St John,
J.D.Rice,
and
J.F.Preston
(2006).
Characterization of XynC from Bacillus subtilis subsp. subtilis strain 168 and analysis of its role in depolymerization of glucuronoxylan.
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J Bacteriol,
188,
8617-8626.
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F.J.Stjohn,
J.D.Rice,
and
J.F.Preston
(2006).
Paenibacillus sp. strain JDR-2 and XynA1: a novel system for methylglucuronoxylan utilization.
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Appl Environ Microbiol,
72,
1496-1506.
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H.Tanaka,
M.Muguruma,
and
K.Ohta
(2006).
Purification and properties of a family-10 xylanase from Aureobasidium pullulans ATCC 20524 and characterization of the encoding gene.
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Appl Microbiol Biotechnol,
70,
202-211.
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K.A.Gray,
L.Zhao,
and
M.Emptage
(2006).
Bioethanol.
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Curr Opin Chem Biol,
10,
141-146.
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K.Manikandan,
A.Bhardwaj,
N.Gupta,
N.K.Lokanath,
A.Ghosh,
V.S.Reddy,
and
S.Ramakumar
(2006).
Crystal structures of native and xylosaccharide-bound alkali thermostable xylanase from an alkalophilic Bacillus sp. NG-27: structural insights into alkalophilicity and implications for adaptation to polyextreme conditions.
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Protein Sci,
15,
1951-1960.
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PDB codes:
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M.Sugimura,
M.Nishimoto,
and
M.Kitaoka
(2006).
Characterization of glycosynthase mutants derived from glycoside hydrolase family 10 xylanases.
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Biosci Biotechnol Biochem,
70,
1210-1217.
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I.von Ossowski,
J.T.Eaton,
M.Czjzek,
S.J.Perkins,
T.P.Frandsen,
M.Schülein,
P.Panine,
B.Henrissat,
and
V.Receveur-Bréchot
(2005).
Protein disorder: conformational distribution of the flexible linker in a chimeric double cellulase.
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Biophys J,
88,
2823-2832.
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Ihsanawati,
T.Kumasaka,
T.Kaneko,
C.Morokuma,
R.Yatsunami,
T.Sato,
S.Nakamura,
and
N.Tanaka
(2005).
Structural basis of the substrate subsite and the highly thermal stability of xylanase 10B from Thermotoga maritima MSB8.
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Proteins,
61,
999.
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PDB codes:
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K.Manikandan,
A.Bhardwaj,
A.Ghosh,
V.S.Reddy,
and
S.Ramakumar
(2005).
Crystallization and preliminary X-ray study of a family 10 alkali-thermostable xylanase from alkalophilic Bacillus sp. strain NG-27.
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Acta Crystallogr Sect F Struct Biol Cryst Commun,
61,
747-749.
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M.Nishimoto,
M.Kitaoka,
S.Fushinobu,
and
K.Hayashi
(2005).
The role of conserved arginine residue in loop 4 of glycoside hydrolase family 10 xylanases.
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Biosci Biotechnol Biochem,
69,
904-910.
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M.R.Proctor,
E.J.Taylor,
D.Nurizzo,
J.P.Turkenburg,
R.M.Lloyd,
M.Vardakou,
G.J.Davies,
and
H.J.Gilbert
(2005).
Tailored catalysts for plant cell-wall degradation: redesigning the exo/endo preference of Cellvibrio japonicus arabinanase 43A.
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Proc Natl Acad Sci U S A,
102,
2697-2702.
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PDB code:
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T.Collins,
C.Gerday,
and
G.Feller
(2005).
Xylanases, xylanase families and extremophilic xylanases.
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FEMS Microbiol Rev,
29,
3.
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G.Zolotnitsky,
U.Cogan,
N.Adir,
V.Solomon,
G.Shoham,
and
Y.Shoham
(2004).
Mapping glycoside hydrolase substrate subsites by isothermal titration calorimetry.
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Proc Natl Acad Sci U S A,
101,
11275-11280.
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PDB codes:
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The most recent references are shown first.
Citation data come partly from CiteXplore and partly
from an automated harvesting procedure. Note that this is likely to be
only a partial list as not all journals are covered by
either method. However, we are continually building up the citation data
so more and more references will be included with time.
Where a reference describes a PDB structure, the PDB
code is
shown on the right.
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Links
