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PDBsum entry 4ev4
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Hydrolase/antibiotic
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PDB id
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4ev4
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References listed in PDB file
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Key reference
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Title
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The basis for carbapenem hydrolysis by class a β-Lactamases: a combined investigation using crystallography and simulations.
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Authors
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F.Fonseca,
E.I.Chudyk,
M.W.Van der kamp,
A.Correia,
A.J.Mulholland,
J.Spencer.
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Ref.
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J Am Chem Soc, 2012,
134,
18275-18285.
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PubMed id
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Note In the PDB file this reference is
annotated as "TO BE PUBLISHED".
The citation details given above were identified by an automated
search of PubMed on title and author
names, giving a
perfect match.
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Abstract
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Carbapenems are the most potent β-lactam antibiotics and key drugs for treating
infections by Gram-negative bacteria. In such organisms, β-lactam resistance
arises principally from β-lactamase production. Although carbapenems escape the
activity of most β-lactamases, due in the class A enzymes to slow deacylation
of the covalent acylenzyme intermediate, carbapenem-hydrolyzing class A
β-lactamases are now disseminating in clinically relevant bacteria. The reasons
why carbapenems are substrates for these enzymes, but inhibit other class A
β-lactamases, remain to be fully established. Here, we present crystal
structures of the class A carbapenemase SFC-1 from Serratia fonticola and of
complexes of its Ser70 Ala (Michaelis) and Glu166 Ala (acylenzyme) mutants with
the carbapenem meropenem. These are the first crystal structures of carbapenem
complexes of a class A carbapenemase. Our data reveal that, in the SFC-1
acylenzyme complex, the meropenem 6α-1R-hydroxyethyl group interacts with
Asn132, but not with the deacylating water molecule. Molecular dynamics
simulations indicate that this mode of binding occurs in both the Michaelis and
acylenzyme complexes of wild-type SFC-1. In carbapenem-inhibited class A
β-lactamases, it is proposed that the deacylating water molecule is deactivated
by interaction with the carbapenem 6α-1R-hydroxyethyl substituent. Structural
comparisons with such enzymes suggest that in SFC-1 subtle repositioning of key
residues (Ser70, Ser130, Asn132 and Asn170) enlarges the active site, permitting
rotation of the carbapenem 6α-1R-hydroxyethyl group and abolishing this
contact. Our data show that SFC-1, and by implication other such
carbapenem-hydrolyzing enzymes, uses Asn132 to orient bound carbapenems for
efficient deacylation and prevent their interaction with the deacylating water
molecule.
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