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PDBsum entry 1a59
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Cold-activity
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PDB id
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1a59
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References listed in PDB file
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Key reference
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Title
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Structural adaptations of the cold-Active citrate synthase from an antarctic bacterium.
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Authors
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R.J.Russell,
U.Gerike,
M.J.Danson,
D.W.Hough,
G.L.Taylor.
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Ref.
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Structure, 1998,
6,
351-361.
[DOI no: ]
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PubMed id
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Abstract
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BACKGROUND: The structural basis of adaptation of enzymes to low temperature is
poorly understood. Dimeric citrate synthase has been used as a model enzyme to
study the structural basis of thermostability, the structure of the enzyme from
organisms living in habitats at 55 degrees C and 100 degrees C having previously
been determined. Here the study is extended to include a citrate synthase from
an Antarctic bacterium, allowing us to explore the structural basis of cold
activity and thermostability across the whole temperature range over which life
is known to exit. RESULTS: We report here the first crystal structure of a
cold-active enzyme, citrate synthase, isolated from an Antarctic bacterium, at a
resolution of 2.09 A. In comparison with the same enzyme from a
hyperthermophilic host, the cold-active enzyme has a much more accessible active
site, an unusual electrostatic potential distribution and an increased relative
flexibility of the small domain compared to the large domain. Several other
features of the cold-active enzyme were also identified: reduced subunit
interface interactions with no intersubunit ion-pair networks; loops of
increased length carrying more charge and fewer proline residues; an increase in
solvent-exposed hydrophobic residues; and an increase in intramolecular ion
pairs. CONCLUSIONS: Enzymes from organisms living at the temperature extremes of
life need to avoid hot or cold denaturation yet maintain sufficient structural
integrity to allow catalytic efficiency. For hyperthermophiles, thermal
denaturation of the citrate synthase dimer appears to be resisted by complex
networks of ion pairs at the dimer interface, a feature common to other
hyperthermophilic proteins. For the cold-active citrate synthase, cold
denaturation appears to be resisted by an increase in intramolecular ion pairs
compared to the hyperthermophilic enzyme. Catalytic efficiency of the
cold-active enzyme appears to be achieved by a more accessible active site and
by an increase in the relative flexibility of the small domain compared to the
large domain.
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The above figure is
reprinted
by permission from Cell Press:
Structure
(1998,
6,
351-361)
copyright 1998.
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