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PDBsum entry 1map
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Aminotransferase
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PDB id
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1map
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References listed in PDB file
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Key reference
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Title
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Crystal structures of true enzymatic reaction intermediates: aspartate and glutamate ketimines in aspartate aminotransferase.
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Authors
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V.N.Malashkevich,
M.D.Toney,
J.N.Jansonius.
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Ref.
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Biochemistry, 1993,
32,
13451-13462.
[DOI no: ]
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PubMed id
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Abstract
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The crystal structures of the stable, closed complexes of chicken mitochondrial
aspartate aminotransferase with the natural substrates L-aspartate and
L-glutamate have been solved and refined at 2.4- and 2.3-A resolution,
respectively. In both cases, clear electron density at the substrate-coenzyme
binding site unequivocally indicates the presence of a covalent intermediate.
The crystallographically identical environments of the two subunits of the alpha
2 dimer allow a simple, direct correlation of the coenzyme absorption spectra of
the crystalline enzyme with the diffraction results. Deconvolution of the
spectra of the crystalline complexes using lognormal curves indicates that the
ketimine intermediates constitute 76% and 83% of the total enzyme populations
with L-aspartate and L-glutamate, respectively. The electron density maps
accommodate the ketimine structures best in agreement with the independent
spectral data. Crystalline enzyme has a much higher affinity for keto acid
substrates compared to enzyme in solution. The increased affinity is interpreted
in terms of a perturbation of the open/closed conformational equilibrium by the
crystal lattice, with the closed form having greater affinity for substrate. The
crystal lattice contacts provide energy required for domain closure normally
supplied by the excess binding energy of the substrate. In solution, enzyme
saturated with amino/keto acid substrate pairs has a greater total fraction of
intermediates in the aldehyde oxidation state compared to crystalline enzyme.
Assuming the only difference between the solution and crystalline enzymes is in
conformational freedom, this difference suggests that one or more substantially
populated, aldehydic intermediates in solution exist in the open conformation.
Quantitative analyses of the spectra indicate that the value of the equilibrium
constant for the open-closed conformational transition of the liganded,
aldehydic enzyme in solution is near 1. The C4' pro-S proton in the ketimine
models is oriented nearly perpendicularly to the plane of the pyridine ring,
suggesting that the enzyme facilitates its removal by maximizing sigma-pi
orbital overlap. The absence of a localized water molecule near Lys258 dictates
that ketimine hydrolysis occurs via a transiently bound water molecule or from
an alternative, possibly more open, structure in which water is appropriately
bound. A prominent mechanistic role for flexibility of the Lys258 side chain is
suggested by the absence of hydrogen bonds to the amino group in the aspartate
structure and the relatively high temperature factors for these atoms in both
structures.
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Secondary reference #1
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Title
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Structural basis for catalysis by aspartate aminotransferase
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Authors
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J.N.Jansonius,
M.G.Vincent.
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Ref.
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biological macromolecules, 1987,
3,
187.
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