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PDBsum entry 4avo
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References listed in PDB file
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Key reference
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Title
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Loop motions important to product expulsion in the thermobifida fusca glycoside hydrolase family 6 cellobiohydrolase from structural and computational studies.
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Authors
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M.Wu,
L.Bu,
T.V.Vuong,
D.B.Wilson,
M.F.Crowley,
M.Sandgren,
J.Ståhlberg,
G.T.Beckham,
H.Hansson.
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Ref.
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J Biol Chem, 2013,
288,
33107-33117.
[DOI no: ]
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PubMed id
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Abstract
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Cellobiohydrolases (CBHs) are typically major components of natural enzyme
cocktails for biomass degradation. Their active sites are enclosed in a tunnel,
enabling processive hydrolysis of cellulose chains. Glycoside hydrolase Family 6
(GH6) CBHs act from nonreducing ends by an inverting mechanism and are present
in many cellulolytic fungi and bacteria. The bacterial Thermobifida fusca Cel6B
(TfuCel6B) exhibits a longer and more enclosed active site tunnel than its
fungal counterparts. Here, we determine the structures of two TfuCel6B mutants
co-crystallized with cellobiose, D274A (catalytic acid), and the double mutant
D226A/S232A, which targets the putative catalytic base and a conserved serine
that binds the nucleophilic water. The ligand binding and the structure of the
active site are retained when compared with the wild type structure, supporting
the hypothesis that these residues are directly involved in catalysis. One
structure exhibits crystallographic waters that enable construction of a model
of the α-anomer product after hydrolysis. Interestingly, the product sites of
TfuCel6B are completely enclosed by an "exit loop" not present in
fungal GH6 CBHs and by an extended "bottom loop". From the structures,
we hypothesize that either of the loops enclosing the product subsites in the
TfuCel6B active site tunnel must open substantially for product release. With
simulation, we demonstrate that both loops can readily open to allow product
release with equal probability in solution or when the enzyme is engaged on
cellulose. Overall, this study reveals new structural details of GH6 CBHs likely
important for functional differences among enzymes from this important family.
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